BÁRBARA CAMPOLINA CARVALHO SILVA
Hiperparatireoidismo primário – novas perspectivas
sobre qualidade óssea através da avaliação por
tomografia computadorizada quantitativa periférica
de alta resolução e escore de osso trabecular
Faculdade de Medicina
Universidade Federal de Minas Gerais
Belo Horizonte – Minas Gerais – Brasil
2012
2
BÁRBARA CAMPOLINA CARVALHO SILVA
Hiperparatireoidismo primário – novas perspectivas
sobre qualidade óssea através da avaliação por
tomografia computadorizada quantitativa periférica
de alta resolução e escore de osso trabecular
Tese apresentada como requisito parcial para
obtenção do título de Doutor no Programa de
Pós-Graduação em Medicina Molecular da
Faculdade de Medicina da Universidade
Federal de Minas Gerais
.
Orientadora: Profa. Maria Marta Sarquis
Soares
Co-Orientador: Prof. John P. Bilezikian
Faculdade de Medicina
Universidade Federal de Minas Gerais
Belo Horizonte – Minas Gerais – Brasil
2012
3
UNIVERSIDADE FEDERAL DE MINAS GERAIS
Reitor
Clélio Campolina Diniz
Pró-Reitor da Pós-graduação
Ricardo Santiago Gomez
Pró-Reitor de Pesquisa
Renato de Lima Santos
FACULDADE DE MEDICINA
Diretor
Francisco José Penna
Vice-Diretor
Tarcizo Afonso Nunes
Coordenador do Centro de Pós-graduação
Manoel Otávio da Costa Rocha
COLEGIADO DO CURSO DE MEDICINA MOLECULAR
Luiz Armando Cunha De Marco (Coordenador)
Débora Marques de Miranda (Subcoordenadora)
Carolina Cavaliéri Gomes
Marco Aurélio Romano Silva
Maria Marta Sarquis Soares
Vitor Bortolo de Rezende (discente, titular)
Luiz Alexandre V. Magno (discente, suplente)
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Para minha preciosa família:
Meu marido Gustavo, pelo amor, companheirismo, paciência e ajuda incondicional. Por
ter dividido esse sonho comigo e me ajudado a torná-lo real. Sem você eu não teria
conseguido. Te amo.
Ao meu amado filho Mateus, pelo sorriso gostoso e abraço confortante, que me enchem a
vida de sentido.
Aos meus queridos irmãos Clarissa e Lucas, companheiros de vida e de jogo, pelo amor,
apoio e torcida constantes.
Aos meus amados pais, Rogério e Marília, meus primeiros e maiores exemplos de amor,
respeito e dedicação. Obrigada pelo apoio e confiança. Começamos esse projeto juntos
há alguns anos e, hoje, dedico-o a vocês.
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AGRADECIMENTOS
Ao Prof. Luiz Armando De Marco pela confiança, presença, conselhos em momentos
críticos e incentivo na realização desse projeto.
À Prof. Marta Sarquis, minha querida orientadora de mestrado e doutorado, pela amizade,
paciência, confiança, incentivo e por despertar meu interesse por doenças
osteometabólicas, pesquisa e ensino.
Ao Prof. John P. Bilezikian, meu orientador, por ter me acolhido na Universidade de
Columbia e me confiado esse importante projeto. Pela ajuda fundamental na elaboração
dos artigos e pelos ensinamentos sobre osteometabolismo, pesquisa clínica e elaboração
de textos científicos. Sobretudo, pelo exemplo profissional e de vida, que me
influenciaram como médica e como pessoa.
À Prof. Stavroula Kousteni por ter me acolhido com tanto carinho em seu laboratório e
me ensinado sobre pesquisa básica, elaboração de projetos e apresentação em público. De
nossa convivência, levo seu exemplo de luta, determinação, e a convicção de que
podemos melhorar sempre.
À Julia Udesky, pela ajuda imprescindível e eficiente no recrutamento de pacientes e
coleta de dados.
Ao Don McMahon e Amy (Chiyuan Zhang) pela ajuda na análise estatística dos dados,
pelas longas e produtivas discussões sobre interpretação dos resultados, e por me
ajudarem a entender um pouco mais sobre estatística.
À Dra Stephanie Boutroy pela ajuda na revisão dos artigos, no entendimento sobre
HRpQCT e, principalmente, por ter me apresentado e me incentivado a utilizar o escore
de osso trabecular.
Ao Dr. Didier Hans pela colaboração na análise do escore de osso trabecular.
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Ao Dr. Edward Guo, chefe do Laboratório de Bioengenharia Óssea do Departamento de
Engenharia Biomédica da Universidade Columbia, e aos engenheiros Bin Zhao e Ji Wang
pela análise de elementos finitos e ITS das imagens de HRpQCT.
Ao Dr. Serge Cremers e Elzbieta Dworakowski, pela realização das dosagens de PTH.
Ao “International Endocrine Scholars Program”, uma parceria entre a Sociedade
Brasileira de Endocrinologia e Metabologia e a Endocrine Society, e em especial à Dra
Valéria Guimarães, ex-coordenadora do programa, por ter proporcionado meu contato
incial com Dr Bilezikian, e o desenvolvimento desse projeto na Universidade de
Columbia.
Ao CNPq, Conselho Nacional de Desenvolvimento Científico e Tecnológico, pelo apoio
no programa de doutorado.
À equipe de endocrinologia do Hospital Felício Rocho pela fundamental ajuda na minha
formação.
À equipe de endocrinologia da Santa Casa de Belo Horizonte por ter me admitido no
ambulatório de Doenças Osteometabólicas, possibilitando aumento da minha vivência
clínica nesta área.
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RESUMO
Introdução: O hiperparatireoidismo primário (PHPT) apresenta-se, nos dias atuais, como
uma doença assintomática ou oligossintomática, diagnosticado pelo achado fortuito de
hipercalcemia. Nesta forma da doença, densitometria óssea revela diminuição de
densidade mineral óssea areal (aBMD) em sítio cortical (rádio 33%), enquanto aBMD na
coluna lombar, composta quase exclusivamente por osso trabecular, é usualmente normal.
Estudos por microtomografia computadorizada (µCT) e histomorfometria de biópsia
óssea de crista ilíaca confirmam preservação de osso trabecular. Esses achados
contradizem o risco aumentado de fraturas vertebrais e não vertebrais no PHPT
assintomático. Tecnologias emergentes, como a tomografia computadorizada quantitativa
periférica de alta resolução (HRpQCT) e escore de osso trabecular (TBS) podem gerar
informações adicionais sobre a microarquitetura e qualidade óssea em pacientes com
PHPT. Além disso, análise de trabécula individual (ITS) e análise de elementos finitos
(FEA) das imagens de HRpQCT fornecem dados detalhados da microestrutura trabecular
e rigidez óssea, que se relacionam à competência biomecânica do esqueleto e risco de
fratura.
Objetivos: Avaliar os compartimentos cortical e trabecular por HRpQCT e FEA, e o
compartimento trabecular através da técnica de ITS em mulheres na pós-menopausa com
PHPT, comparando-as com controles saudáveis. Correlacionar TBS com medidas por
HRpQCT no PHPT.
Pacientes e métodos: 51 mulheres na pós menopausa portadoras de PHPT e 120
controles saudáveis foram avaliados por HRpQCT, ITS e FEA. TBS foi estimado em
subgrupo de 22 mulheres com PHPT.
Resultados: aBMD da coluna lombar avaliada por densitometria óssea foi similar em
pacientes e controles. No entanto, resultados da HRpQCT revelaram redução importante
da densidade volumétrica total, cortical e trabecular em indivíduos com PHPT. Não
apenas redução da espessura cortical, mas também maior espaçamento entre as trabéculas
e distribuição trabecular heterogênea foram observadas no rádio e na tíbia de pacientes
com PHPT. No rádio, observou-se ainda redução da espessura e número trabecular.
Alterações trabeculares foram mais evidentes no rádio do que na tíbia. ITS revelou, em
ambos sítios ósseos, redução das trabéculas em placa, com consequente redução da razão
placa-haste. Diminuição da densidade de junções entre placas e entre hastes e placas
foram observadas no rádio e tíbia. No rádio, houve também diminuição da densidade de
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junções entre hastes. Essas anormalidades trabeculares e corticais resultaram em
diminuição da rigidez do osso inteiro e trabecular. TBS correlacionou-se com índices
determinados pela HRpQCT no rádio, com exceção de espessura trabecular (Tb.Th) e
rigidez trabecular. Na tíbia, correlações foram observadas entre TBS e densidades
volumétricas, espessura cortical, volume ósseo trabecular e rigidez de osso inteiro. Neste
sítio ósseo, correlação de TBS com todas as medidas de microarquitetura trabecular,
exceto Tb.Th, foi observada após ajuste para peso corporal.
Conclusão: Anormalidades da densidade e microarquitetura esquelética são universais no
PHPT, não se limitando ao compartimento cortical, explicando o achado de redução da
rigidez óssea total e trabecular e, possivelmente, risco aumentado de fratura no PHPT.
Uma vez que HRpQCT não é um exame amplamente disponível em nosso meio, o achado
de correlação significativa entre TBS e HRpQCT indica que o TBS poderia tornar-se útil
na avaliação clínica desses pacientes.
Descritores: hiperparatireoidismo primário, paratormônio, tomografia computadorizada
quantitativa periférica de alta resolução (HRpQCT), escore de osso trabecular (TBS),
análise de trabécula individual (ITS), análise de elementos finitos (FEA).
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ABSTRACT
Introduction: Primary hyperparathyroidism (PHPT) is predominantly an asymptomatic
disease, diagnosed by the fortuitous finding of hypercalcemia. Typically, in this milder
form of the disease, areal bone mineral density (aBMD) by DXA is reduced at the 1/3
radius, a site of predominantly cortical bone, while the lumbar spine, a site of
predominantly cancellous bone, is generally well preserved. Histomorphometric and
micro-computed tomography (µCT) analyses of iliac crest bone biopsies have confirmed
these DXA results in PHPT by showing reduced cortical elements whereas the trabecular
compartment appears to be relatively well preserved. These findings, however, are
inconsistent with numerous epidemiological reports showing an increased in fracture risk
at both vertebral and non-vertebral sites in PHPT. Emerging technologies, such as high-
resolution peripheral quantitative computed tomography (HRpQCT), and trabecular bone
score (TBS) may provide additional insight into microstructural features and bone quality
in PHPT. Moreover, individual trabecula segmentation (ITS) and finite element analysis
(FEA) of HRpQCT images offer even more detailed information about trabecular bone
and bone stiffness, estimating the biomechanical competence of bone, and fracture risk in
PHPT
Aims: To evaluate both cortical and trabecular compartments by HRpQCT and FEA, and
the trabecular compartment by ITS analysis, in postmenopausal women with PHPT, as
compared to healthy controls. To correlate TBS with HRpQCT measurements in PHPT.
Patients and Methods: HRpQCT, ITS and FE analyses were performed in 51
postmenopausal women with PHPT and 120 controls. TBS was assessed in a subgroup of
22 women with PHPT.
Results: aBMD at the lumbar spine by DXA was similar in cases and controls. However,
women with PHPT showed, at both sites, decreased volumetric densities at trabecular and
cortical compartments, thinner cortices, and more widely spaced and heterogeneously
distributed trabeculae. At the radius, trabeculae were thinner and fewer in PHPT. The
radius was affected to a greater extent in the trabecular compartment than the tibia. ITS
analyses revealed, at both sites, that plate-like trabeculae were depleted, with a resultant
reduction in the plate/rod ratio. Microarchitectural abnormalities were evident by
decreased plate-rod and plate-plate junctions at the radius and tibia, and rod-rod junctions
at the radius. These trabecular and cortical abnormalities resulted in decreased whole
bone stiffness and trabecular stiffness. TBS was correlated with all HRpQCT and
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mechanical measurements except for trabecular thickness (Tb.Th), and trabecular
stiffness at the radius. At the tibia, correlations were observed between TBS and
volumetric densities, cortical thickness, trabecular bone volume, and whole bone
stiffness. All indices of trabecular microarchitecture, except Tb.Th, correlated with TBS
after adjusting for body weight.
Conclusion: These results provide evidence that in PHPT, reduced volumetric densities
and microstructural abnormalities are pervasive and not limited to the cortical
compartment. These abnormalities seen by HRpQCT are likely to reflect reduced bone
strength and may help to account for increased global fracture risk in PHPT. With
significant correlations of TBS with mechanical and microstructural indices by HRpQCT,
a method that is not generally available, TBS could become a helpful clinical tool in the
assessment of trabecular microstructure in PHPT.
Key words: primary hyperparathyroidism, parathyroid hormone, high-resolution
peripheral quantitative computed tomography (HRpQCT), trabecular bone score (TBS),
individual trabecular segmentation (ITS), finite element analysis (µFEA).
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LISTA DE ILUSTRAÇÕES
INTRODUÇÃO:
FIGURA 1 - Padrão densitométrico típico do hiperparatireoidismo primário nos dias
atuais................................................................................................................
22
FIGURA 2 - Microarquitetura em mulheres saudáveis e com PHPT................................... 22
FIGURA 3 - Imagens de osso trabecular segmentado em trabéculas individuais................ 27
FIGURA 4 Princípios do escore de osso trabecular........................................................... 31
ARTIGO 1:
FIGURA 1 - Representative HRpQCT images of the distal radius of PHPT....................... 51
FIGURA 2 - Comparison of HRpQCT results at the distal radius and tibia in PHPT and
control groups.................................................................................................. 52
FIGURA 3 - Comparison of the ITS and µFEA results at the distal radius and tibia in
PHPT and control groups................................................................................. 53
FIGURA 4 - Correlations between PTH and Tb.vBMD (A) and Tb.Th (B) at the radius,
and Ct.vBMD (C) and Ct.Th (D) at the tibia, in the PHPT
group................................................................................................................
54
ARTIGO 2:
FIGURA 1 - Comparison of aBMD by DXA and TBS........................................................ 81
FIGURA 2 - Correlations adjusted for body weight between TBS and trabecular number,
trabecular separation, and stiffness at the radius; and trabecular number,
trabecular separation, and stiffness at the tíbia................................................
82
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LISTA DE TABELAS
ARTIGO 1:
TABELA 1 - Baseline clinical, biochemical and densitometric data of 51 PHPT and 120
control subjects............................................................................................... 55
TABELA 2 - Bone geometry, density and microarchitecture by HRpQCT in PHPT
patients and controls....................................................................................... 56
TABELA 3 - ITS and mechanical parameters in PHPT patients and controls.................... 57
TABELA 4 - Correlations (r values) between BMI and HRpQCT parameters at the
radius and at the tibia in subjects with PHPT and controls............................
58
ARTIGO 2:
TABELA 1 - Baseline characteristics of 22 subjects with PHPT........................................ 83
TABELA 2 - Correlation between TBS and HRpQCT/mechanical parameters at the
radius and tibia in subjects with PHPT.......................................................... 84
TABELA 3 - Univariate or multivariate linear regression analysis to predict the
variability in HRpQCT indices and mechanical
parameters......................................................................................................
85
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LISTA DE ABREVIATURAS
1,25(OH)2D 1,25 di-hidroxi-vitamina D
25OHD 25 hidroxi-vitamina D
aBMD densidade mineral óssea areal (do inglês, areal bone mineral density)
aBV/TV fração do volume ósseo orientado em sentido axial (do inglês, axial bone
volume fraction)
BMI índice de massa corporal (do inglês, body mass index)
BV/TV volume ósseo (do inglês, bone volume)
Conn.D densidade da conectividade trabecular (do inglês, conectivity density)
Ct.Th espessura cortical (do inglês, cortical thickness)
Ct.vBMD densidade mineral óssea volumétrica cortical (do inglês, cortical volumetric
bone mineral density)
Ctload distal porcentagem de carga suportada pelo compartimento cortical na superfície
distal (do inglês, cortical load at distal surface)
Ctload proximal porcentagem de carga suportada pelo compartimento cortical na superfície
proximal (do inglês, cortical load at proximal surface)
DXA medida da absorção de raio-X de dupla energia (do inglês, dual energy X-ray
absortiometry)
FEA análise de elementos finitos (do inglês, finite element analysis)
HPT-JT síndrome hiperparatireoidismo-tumor de mandíbula (do inglês,
hyperparathyroidism-jaw tumor syndrome)
HRpQCT tomografia computadorizada quantitativa periférica de alta resolução (do
inglês, high resolution peripheric quantitative computadorized tomography)
ITS Análise de trabécula individual (do inglês, individual trabecula
segmentation)
MEN-1 neoplasia endócrina múltipla tipo 1 (do inglês, multiple endocrine neoplasia
type 1)
MEN-2a neoplasia endócrina múltipla tipo 2a (do inglês, multiple endocrine
neoplasia type 2a)
P-P Junc.D densidade de junções entre placas (do inglês, plate-plate junction density)
P-R Junc.D densidade de junções entre placas e hastes (do inglês, plate-rod junction
density)
Razão P-R Razão placa-haste (do inglês, plate-rod ratio)
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pBV/TV Fração de volume ósseo em placas (do inglês, plate bone volume fraction)
PHPT hiperparatireoidismo primário (do inglês, primary hyperparathyroidism)
pQCT tomografia computadorizada quantitativa periférica (do inglês, peripheric
quantitative computadorized tomography)
pTb.N número de trabéculas em placas (do inglês, trabecular plate number)
pTb.S área de superfície média das trabéculas em placa (do inglês, mean trabecular
plate surface area)
pTb.Th espessura média de trabéculas em placas (do inglês, mean trabecular plate
thickness)
PTH paratormônio
R-R Junc.D densidade de junções entre hastes (do inglês, rod-rod junction density)
rBV/TV Fração de volume ósseo em hastes (do inglês, rod bone volume fraction)
rTb. ℓ comprimento médio das trabéculas em haste (do inglês, mean trabecular rod
length)
rTb.N número de trabéculas em hastes (do inglês, trabecular rod number)
rTb.Th espessura média de trabéculas em hastes (do inglês, mean trabecular rod
thickness)
Tb.N número de trabéculas (do inglês, trabecular number)
Tb.Sp Separação trabecular (do inglês, trabecular separaration)
Tb.Sp.SD desvio padrão da separação trabecular ou distribuição trabecular (do inglês,
trabecular separation standard deviation ou trabecular distribution)
Tb.Th espessura trabecular (do inglês, trabecular thichness)
Tb.vBMD densidade mineral óssea volumétrica trabecular (do inglês, trabecular
volumetric bone mineral density)
TBS escore de osso trabecular (do inglês, trabecular bone score)
vBMD densidade mineral óssea volumétrica (do inglês, volumetric bone mineral
density)
µCT microtomografia computadorizada (do inglês, micro-computed tomography)
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SUMÁRIO
1- INTRODUÇÃO:
1.1- Hiperparatireoidismo Primário…………………………………………………………… 17
1.1.1- Etiologia e patogênese………………………………………………………………….. 17
1.1.2- Apresentação clínica do PHPT – forma clássica……………………………………….. 19
1.1.3- Apresentação clínica do PHPT nos dias atuais………………………………………… 20
1.1.4- Risco de fratura no PHPT……………………………………………………………… 22
1.2- Tomografia computadorizada quantitativa periférica de alta resolução…………………. 24
1.2.1- Análise de trabécula individual…………………………………………………... 26
1.2.2- Análise de elementos finitos…………………………………………………………… 27
1.3- Escore de osso trabecular………………………………………………………………… 28
2- OBJETIVOS………………………………………………………………………………. 32
3- RESULTADOS
3.1- Artigo 1…………………………………………………………………………………... 33
Abstract………………………………………………………………………………. 35
Introduction…………………………………………………………………………... 36
Patients and Methods…………………………………………………………………. 38
Results………………………………………………………………………………... 42
Discussion……………………………………………………………………………. 46
Figures………………………………………………………………………………... 51
Tables………………………………………………………………………………… 55
References……………………………………………………………………………. 59
3.2- Artigo 2…………………………………………………………………………………... 66
Abstract………………………………………………………………………………. 68
Introduction…………………………………………………………………………... 69
Patients and Methods…………………………………………………………………. 71
Results………………………………………………………………………………... 74
Discussion……………………………………………………………………………. 76
Figures………………………………………………………………………………... 81
Tables………………………………………………………………………………… 83
References……………………………………………………………………………. 86
4- CONSIDERAÇÕES FINAIS.……………………………………………………………. 92
5- CONCLUSÕES…………………………………………………………………………… 97
6- REFERÊNCIAS BIBLIOGRÁFICAS…………………………………………………... 98
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7- ANEXOS
Artigo de revisão publicado sobre o tema…………………………………............................ 106
Declaração de aprovação.......................................................................................................... 116
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1- INTRODUÇÃO:
1.1- Hiperparatireoidismo Primário:
Hiperparatireoidismo primário (PHPT) é uma doença endócrina comum causada por
disfunção de uma ou mais glândulas paratireoides, resultando, tipicamente, em
hipercalcemia e níveis elevados ou inapropriadamente normais de paratormônio (PTH)
(BRINGHURST et al., 2008). Constitui a causa mais comum de hipercalcemia em
pacientes ambulatoriais. As mulheres são mais afetadas que os homens, em uma relação
de 3:1. O pico de incidência da doença é a sexta década de vida, sendo raramente
encontrada em indivíduos menores de 15 anos de idade (VIEIRA, 2007; BRINGHURST
et al., 2008).
O excesso de PTH leva a maior reabsorção renal de cálcio, fosfatúria, aumento da síntese
de 1,25 diidroxi-vitamina D [1,25(OH)2D] e aumento da reabsorção óssea, perpetuando a
hipercalcemia. Os resultados dessas ações evidenciam-se nas manifestações bioquímicas
da doença, que além de hipercalcemia, cursa com hipofosfatemia, ou, mais comumente,
fósforo sérico no limite inferior da normalidade, redução dos níveis séricos de 25 hidroxi-
vitamina D (25OHD) e aumento dos níveis circulantes de 1,25(OH)2D (HOLICK, 2007;
BILEZIKIAN, 2012). Calciúria de 24 horas é normal ou aumentada, devido ao aumento
da carga filtrada de cálcio. Marcadores de remodelação óssea são tipicamente elevados,
indicando aumento da reabsorção e formação ósseas (BILEZIKIAN, 2012).
1.1.1- Etiologia e patogênese:
O PHPT é causado, em 80% dos casos, por adenoma de uma das glândulas paratireoides.
Múltiplos adenomas são encontrados em 2 a 4% dos pacientes, e algumas vezes, esses
tumores benignos localizam-se em regiões anatômicas que não as lojas paratireoidianas.
Adenomas ectópicos são encontrados, mais comumente, dentro da glândula tireoide,
mediastino superior ou timo (BILEZIKIAN et al., 2012). Em aproximadamente 15% dos
pacientes, o PHPT é causado por hiperplasia das 4 glândulas paratireoides e, muito
raramente, em menos de 1% dos casos, câncer de paratireoide é a causa do PHPT
(BRINGHURST et al., 2008). Nesses casos, a doença tende a apresentar-se de forma
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mais grave, com níveis calcêmicos muito elevados e sintomas evidentes (MARCOCCI et
al., 2008).
Na grande maioria dos casos, o PHPT é esporádico e causado por mutação no DNA das
células principais da paratireoide, ocasionando sua expansão clonal, com consequente
formação do adenoma (ARNOLD et al., 1988). Mutações somáticas ativadoras do
oncogene Cyclin D1, ou inativadoras do gene supressor de tumor MEN1 foram descritas
em pacientes portadores de adenoma da paratireoide (ARNOLD et al., 2002). A origem
do PHPT esporádico causado por hiperplasia das paratireoides é desconhecida, mas
acredita-se que estímulos extra-paratireoidianos ou anormalidades genéticas presentes nas
quatro glândulas contribuam para a proliferação celular anormal observada nessa
condição (BRINGHURST et al., 2008). Diferente do adenoma, a hiperplasia resulta de
uma expansão policlonal das células principais da paratireoide (ARNOLD et al., 1988).
Em casos esporádicos de carcinoma de paratireoide, mutações somáticas foram
identificadas nos genes HRPT2, Cyclin D1, Rb, p53 e BRCA2 (MARCOCCI et al., 2008).
As formas hereditárias de PHPT são raras, mas seu conhecimento é de fundamental
importância, uma vez que requerem manejo diferenciado (SARQUIS et al., 2008). As
principais formas familiares de PHPT são as síndromes de neoplasia endócrina múltipla
tipo 1 (MEN-1) e 2a (MEN-2a) e a síndrome hiperparatireoidismo-tumor de mandíbula
(HPT-JT), associadas a mutações germinativas nos genes MEN1, RET e HRPT2,
respectivamente (BRANDI et al., 2001). Além do PHPT, presente em quase 100% dos
portadores de MEN-1, tumores hipofisários e de ilhotas pancreáticas caracterizam essa
síndrome. Na MEN-2a, caracterizada por carcinoma medular de tireoide e
feocromocitoma, PHPT é evidente em apenas 5 a 20% dos pacientes. As duas condições
manifestam-se em indivíduos mais jovens e, quando presente, o PHPT é mais
frequentemente causado por hiperplasia (MARX et al., 2002). Na síndrome HPT-JT,
tumores fibrosos da mandíbula associam-se ao quadro de PHPT, sendo o carcinoma de
paratireoide mais incidente nessa entidade (MARX et al., 2002). Finalmente, o
hiperparatireoidismo familiar isolado, outra forma hereditária de PHPT, não se
acompanha de manifestações clínicas ou marcadores genéticos definidos (SIMONDS et
al., 2002).
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1.1.2- Apresentação clínica do PHPT – forma clássica
Manifestações clínicas do PHPT resultam de sinais e sintomas relacionados à
hipercalcemia (fraqueza muscular, depressão, apatia, poliúria, desidratação, constipação
intestinal, coma), aumento da excreção renal de cálcio (nefrocalcinose, nefrolitíase,
insuficiência renal) e/ou aumento da reabsorção óssea (osteíte fibrosa cística e fraturas
por fragilidade) (VIEIRA, 2007; BRINGHURST et al., 2008).
Os primeiros relatos de PHPT retratam uma condição de alta morbi-mortalidade
(WILSON et al., 1964). Sintomas neuro-psiquiátricos incluíam cefaleia, depressão,
confusão mental, letargia e coma. Em 1949, Patten e colegas descreveram síndrome
neuromuscular própria do PHPT, caracterizada por fraqueza muscular simétrica
periférica, distúrbio da marcha, atrofia muscular, hiperreflexia generalizada e
fasciculações da língua (PATTEN et al., 1974). Sintomas gastro-intestinais como
anorexia, náusea, vômitos e constipação eram observados com frequência. Além disso,
pancreatite aguda e úlceras pépticas foram descritas em associação com a doença
(KEATING, 1961). Poliúria e polidipsia graves, algumas vezes diagnosticadas como
diabetes insipidus, foram também relatadas (COPE, 1966). Redução da função renal,
nefrocalcinose e nefrolitíase eram evidentes. Antes de 1965, nefrolitíase era observada em
até 80% dos pacientes com PHPT (KEATING, 1961; WILSON et al., 1964). Nessa
época, o diagnóstico de PHPT envolvia testes metabólicos complexos, uma vez que a
dosagem sérica de PTH tornou-se disponível anos depois, em 1963 (BERSON et al.,
1963).
O envolvimento esquelético característico do PHPT, osteíte fibrosa cística, foi reportado
pela primeira vez em 1891, por von Recklinghausen. No entanto, o reconhecimento de
disfunção das paratireoides como causa da doença óssea deu-se mais tarde, em 1925,
quando Mandl observou, em paciente jovem do sexo masculino, remissão das lesões
ósseas após remoção cirúrgica de tumor da paratireoide (ALBRIGHT, 1948). Em 1926,
Albright, Aub e Bauer estudaram o primeiro paciente diagnosticado com PHPT nos EUA,
cujo adenoma de paratireoide, localizado na região torácica, foi removido após 6
explorações cirúrgicas mal sucedidas (ALBRIGHT, 1948). Antes da localização do
adenoma, o paciente foi tratado clinicamente com dieta rica em cálcio, o que, apesar de
aumentar seus níveis calcêmicos, contribuiu significativamente para melhora de sua
doença óssea (POTTS, 2005). Nas décadas subsequentes, osteíte fibrosa cística foi
20
observada em vários pacientes com PHPT (KEATING, 1961; WILSON et al., 1964;
COPE, 1966; MALLETTE et al., 1974). Achados característicos dessa condição são: 1-
desmineralização óssea generalizada; 2- reabsorção subperióstea, mais evidente em
falanges e região distal das clavículas; 3- aspecto em “sal e pimenta” à radiografia de
crânio; 4- cistos ósseos, normalmente múltiplos, mais frequentes em metacarpos, ossos
longos, pélvis e crânio; 5- osteoclastomas ou tumores marrons, que são tumores
compostos por múltiplos osteoclastos e células estromais, encontrados mais
frequentemente em ossos longos, costelas e mandíbula; e 6: fraturas patológicas.
Clinicamente, pacientes acometidos por osteíte fibrosa cística podem apresentar dor
óssea, cifose torácica, redução de estatura e colapso lateral da costela ou pélvis
(BRINGHURST et al., 2008).
1.1.3- Apresentação clínica do PHPT nos dias atuais
Após a década de 70, a instituição de dosagens de cálcio em exames de rotina mudou
consideravelmente a forma de apresentação do PHPT em países desenvolvidos. Nos dias
atuais, o PHPT é uma doença sobretudo assintomática, sendo descoberta pelo achado
fortuito de hipercalcemia (SILVERBERG et al., 1999; ADAMI et al., 2002;
BILEZIKIAN et al., 2005; RUBIN et al., 2008). No Brasil, a frequência de pacientes
sintomáticos ainda é considerável, constituindo cerca de 40 a 50% dos casos (KULAK et
al., 1998; OHE et al., 2005; BANDEIRA et al., 2006). Estudo brasileiro mais recente
envolvendo 91 pacientes portadores de PHPT evidenciou nefrolitíase e fratura por
fragilidade em 52 e 4% dos casos, respectivamente (NEVES et al., 2012). No entanto,
observa-se, também em nosso meio, redução da frequência de doença sintomática nos
últimos anos (OHE et al., 2005).
A forma assintomática ou oligossintomática de PHPT apresenta-se, com frequência, com
hipercalcemia leve e, portanto, sintomas sistêmicos decorrentes de elevação da calcemia
estão, tipicamente, ausentes. Da mesma forma, nefrolitíase é reportada em apenas 10 a
25% dos casos (MOLLERUP et al., 2002; RUBIN et al., 2008). Sintomas
neuropsiquiátricos como fraqueza, esquecimento, cansaço fácil, depressão e ansiedade,
podem estar presentes mesmo nas formas leves de PHPT, podendo ou não melhorar com
o tratamento cirúrgico da doença (PASIEKA et al., 2002; QUIROS et al., 2003;
BOLLERSLEV et al., 2007; WALKER et al., 2009). Sintomas cardiovasculares como
21
hipertensão arterial, hipertrofia de ventrículo esquerdo, espessamento da camada médio-
intimal da artéria carótida, calcificação miocárdica e valvular também foram reportados
em vários estudos, mas não confirmados por outros (SILVERBERG et al., 2009;
WALKER et al., 2010; CARRELLI et al., 2012; IWATA et al., 2012). Da mesma forma,
a melhora desses parâmetros não é regra após paratireoidectomia, e portanto, a
importância desses achados no PHPT assintomático requer investigação adicional
(SILVERBERG et al., 2009).
O achado de osteíte fibrosa cística em pacientes com PHPT é raro nos dias atuais. Em
pacientes com PHPT assintomático, o acometimento esquelético é notado sobretudo pelo
achado de osteoporose. No entanto, diferente de outras causas secundárias de
osteoporose, o padrão de redução da densidade mineral óssea areal (aBMD) por medida
da absorção de raio-X de dupla energia (DXA) é compatível com perda óssea cortical e
preservação óssea trabecular. Esse conceito fundamenta-se na observação de que há
propensão para maior redução da aBMD em rádio 33%, sítio ósseo composto
predominantemente por osso cortical. Por outro lado, aBMD em coluna lombar, sítio
ósseo essencialmente trabecular, tende a ser preservada quando comparada a indivíduos
controle da mesma idade (SILVERBERG et al., 1989; RUBIN et al., 2008) (Figura 1).
Confirmando esses achados densitométricos, histomorfometria de biópsia de crista ilíaca
revela deterioração do compartimento cortical e preservação do compartimento trabecular
em homens e mulheres na pré e pós menopausa portadores de PHPT. Quando
comparados a controles da mesma idade e sexo, pacientes com PHPT possuem espessura
cortical reduzida. No entanto, apresentam volume ósseo trabecular (BV/TV), número de
trabéculas (Tb.N) e densidade da conectividade trabecular (Conn.D) maiores ou similares
ao grupo controle (PARISIEN et al., 1990; CHRISTIANSEN et al., 1992; PARISIEN et
al., 1992; PARISIEN et al., 1995). Em pacientes com PHPT, separação trabecular
(Tb.Sp) é menor (PARISIEN et al., 1990) e espessura trabecular (Tb.Th) é menor ou
similar a controles normais (PARISIEN et al., 1990; CHRISTIANSEN et al., 1992). Da
mesma forma, análise de biópsia de crista ilíaca por microtomografia computadorizada
(µCT) confirmou que, quando comparadas a mulheres sadias na pós menopausa,
mulheres na pós menopausa com PHPT apresentam BV/TV e Conn.D aumentados, e
Tb.Sp diminuída (DEMPSTER et al., 2007). Mulheres na pré-menopausa com PHPT
possuem BV/TV semelhante a mulheres sadias de mesmo estado menopausal (Figura 2).
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Figura 1: Padrão densitométrico típico do hiperparatireoidismo primário nos dias atuais.
Densidade mineral óssea areal da coluna lombar, colo do fêmur e rádio apresentada em
comparação a valores esperados para controles normais.
Adaptado de (SILVERBERG et al., 1989)
Figura 2: Microarquitetura em mulheres saudáveis e com PHPT. Reconstruções em 3D
de imagens de microtomografia computadorizada de osso trabecular em mulheres com
PHPT na pré e pós-menopausa (B e D) e controles sadios (A e C).
Adaptado de (DEMPSTER et al., 2007).
1.1.4- Risco de fratura no PHPT
Apesar do padrão densitométrico típico do PHPT, com redução preferencial da aBMD em
sítio cortical, confirmada por achados inequívocos de preservação de microarquitetura e
volume trabecular em biópsias de crista ilíaca, numerosos estudos identificaram risco
aumentado de fratura vertebral e não vertebral em pacientes com PHPT
23
(KOCHERSBERGER et al., 1987; KHOSLA et al., 1999; VESTERGAARD and
MOSEKILDE, 2003; VIGNALI et al., 2009; YU et al., 2010). Pacientes avaliados nesses
estudos eram, em sua maioria, portadores da forma assintomática da doença, e o número
de indivíduos avaliados variou de 150 a 1.700. Risco global de fratura, assim como risco
de fratura vertebral, pélvica, em costela e rádio foram maiores em pacientes com PHPT
do que em indivíduos controles. Fratura de fêmur foi marginalmente mais incidente em
indivíduos com PHPT (KHOSLA et al., 1999). Análise prospectiva avaliando quase
2.000 pacientes com PHPT evidenciou aumento do risco de fratura de fêmur apenas em
um subgrupo de homens submetidos a paratireoidectomia para tratamento da doença, mas
não em toda a população do estudo (LARSSON et al., 1993). Finalmente, risco de fratura
vertebral foi semelhante em pacientes com PHPT assintomático e controles históricos
(WILSON et al., 1988). Apesar de alguns achados divergentes, grande maioria dos
relatos aponta para risco aumentado de fraturas em PHPT e, portanto, reavaliação do
conceito estabelecido de preservação do osso trabecular nessa entidade faz-se necessária.
Métodos de imagem não invasivos que permitam a avaliação individualizada dos
compartimentos trabecular e cortical poderiam trazer informações adicionais e ser mais
pertinentes à discussão do risco de fratura no PHPT assintomático. De fato, estudos de
pacientes com PHPT por tomografia computadorizada quantitativa periférica (pQCT),
avaliando tanto o rádio (CHEN et al., 2003), quanto a tíbia (CHAROPOULOS et al.,
2006), evidenciam efeitos negativos do PTH em ambos os compartimentos esqueléticos.
Esta tecnologia permite, através da avaliação de sítios periféricos com resolução de 500 a
590µm, a diferenciação dos compartimentos cortical e trabecular, além de avaliar a
geometria óssea. Mais recentemente, estudo por tomografia computadorizada quantitativa
periférica de alta resolução (HRpQCT), revelou perda óssea tanto cortical quanto
trabecular em rádio distal em mulheres com PHPT (HANSEN et al., 2010). Este estudo,
no entanto, envolveu apenas 26 pacientes com PHPT e, as alterações em osso trabecular
não foram confirmadas na tíbia. Além do mais, não se estudou se as alterações estruturais
encontradas afetariam a competência biomecânica do osso. Portanto, estudos adicionais
para avalição esquelética de pacientes com PHPT, utilizando técnicas de imagem não
invasivas, que permitam análise do esqueleto trabecular com mais acurácia, poderiam
trazer informações adicionais a respeito da qualidade óssea nessa doença, ampliando
nosso conhecimento acerca do risco de fratura em pacientes com PHPT.
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1.2- Tomografia Computadorizada Quantitativa periférica de Alta Resolução
(HRpQCT):
HRpQCT é um método não invasivo que permite a avaliação in vivo da geometria,
densidade mineral óssea volumétrica (vBMD) e microarquitetura dos compartimentos
cortical e trabecular (BURGHARDT et al., 2011). A utilização da HRpQCT para
avaliação esquelética no PHPT é particularmente atraente, uma vez que acredita-se que o
PTH exerça ações diferentes nos compartimentos cortical e trabecular. Além de avaliar
geometria, vBMD e microarquitetura, métodos adicionais de avaliação têm sido aplicados
a imagens de HRpQCT para avaliação mais detalhada da estrutura trabecular e da
competência biomecânica do esqueleto.
HRpQCT foi desenvolvida para o estudo in vivo da extremidade distal do rádio e da tíbia
com resolução suficiente (tamanho de voxel= 82 µm) para fornecer informações acerca
da microestrutura trabecular e cortical, disponíveis anteriormente apenas através de
estudos histomorfométricos de biópsia óssea. Além de ser um método de alta resolução,
HRpQCT tem a vantagem de oferecer uma dose de radiação ionizante baixa (radiação
efetiva de 1 a 3 mSv), não expondo órgãos internos aos efeitos nocivos da radiação
(DAMILAKIS et al., 2010). No entanto, a HRpQCT é uma técnica de alto custo e,
portanto, poucos centros médicos no mundo têm acesso a essa tecnologia. Apesar de
avaliar o rádio distal, área comumente sujeita a fratura osteoporótica (Fratura de Colles),
HRpQCT não avalia sítios ósseos centrais como fêmur e coluna lombar, importantes
alvos de fratura por fragilidade.
O instrumento utilizado para a realização do exame é fornecido atualmente por um único
fabricante (XtremeCT; Scanco Medical AG, Brüttisellen, Suíça). Para a realização do
exame, uma primeira imagem da região de interesse é adquirida em posição ântero-
posterior e uma linha de referência é traçada na região distal do rádio e da tíbia. Uma
série de 110 imagens paralelas sequenciais são então adquiridas, sendo a primeira obtida
a 9,5 mm proximal à linha de referência do rádio e 22,5 mm proximal à linha de
referência da tíbia. As imagens são reconstruídas, fornecendo uma imagem em 3
dimensões com 9 mm de comprimento (BOUTROY et al., 2005; KHOSLA et al., 2006).
Análise da imagem reconstruída se dá a partir de um protocolo padrão fornecido pelo
fabricante. Os parâmetros fornecidos por essa análise-padrão e utilizados nesse trabalho
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são: área total, que equivale à área de secção transversal; densidade mineral óssea
volumétrica total (Total vBMD), cortical (Ct.vBMD) e trabecular (Tb.vBMD); espessura
cortical (Ct.Th); volume ósseo trabecular (BV/TV); número trabecular (Tb.N); espessura
trabecular (Tb.Th); separação trabecular (Tb.Sp) e desvio padrão da separação trabecular
(Tb.Sp.SD). Essas variáveis são calculadas diretamente, ou a partir do cálculo das
variáveis estimadas de forma direta.1
Apesar de apresentar correlação modesta com a histomorfometria quando diferentes
regiões ósseas são avaliadas (COHEN A., et al., 2010), medidas de microarquitetura
avaliados por HRpQCT correlacionam-se significativamente com resultados de
histomorfometria ou µCT avaliados em mesmas regiões ósseas (MACNEIL and BOYD,
2007; BOUTROY et al., 2011). Estudos clínicos iniciais para avaliação do método
demonstraram que a HRpQCT é capaz de detectar diferenças na microestrutura óssea
entre homens e mulheres, bem como alterações relacionadas ao envelhecimento ou a
outras causas de perda óssea (BOUTROY et al., 2005; KHOSLA et al., 2006). Mais
recentemente, vários estudos confirmaram que medidas de densidade mineral óssea
volumétrica e microarquitetura óssea por HRpQCT distinguem indivíduos com história
de fraturas vertebrais e não vertebrais de controles normais, independentemente de aBMD
em rádio ultra-distal ou fêmur total (SORNAY-RENDU et al., 2007; VICO et al., 2008;
STEIN et al., 2010; STEIN et al., 2011; STEIN et al., 2012).
1As seguintes variáveis são calculadas de modo direto: área total, Total vBMD, Ct.vBMD, Tb.VBMD,
Ct.Th e Tb.N. O cálculo do BV/TV é derivado de Tb.vBMD, assumindo que um osso totalmente
mineralizado tem densidade de 1.200 mg de hidroxiapatita por centímetro cúbico (BV/TV (%)= 100 X
(Tb.vBMD/1.200). Uma vez que a HRpQCT tem resolução suficiente para medir a distância entre as
trabéculas, a medida do Tb.N é determinada diretamente medindo o inverso do distância média entre as
trabéculas. Por outro lado, a espessura média das trabéculas, entre 100 e 150µm, limita sua visualização,
uma vez que cada trabécula ocupa 1 a 2 voxels. Dessa forma seu cálculo é derivado de BV/TV e Tb.N:
Tb.Th= (BV/TV)/ Tb.N. O cálculo da Tb.Sp é feito de maneira semelhante (Tb.Sp=(1−BV/TV)/Tb.N).
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1.2.1- Análise de trabécula individual (ITS)
Análise de trabécula individual (ITS) é uma nova técnica de análise do compartimento
trabecular em imagens de alta resolução. A técnica foi desenvolvida por Liu e Guo (LIU
et al., 2008) e inicialmente aplicada a imagens de µCT obtidas de amostras ósseas de colo
de fêmur, tíbia proximal e vértebras lombares. Mais recentemente, ITS foi validada para
análise de imagens de HRpQCT (LIU et al., 2011a).
A estrutura do osso trabecular é constituída por uma rede interconectada de hastes e
placas. A técnica de ITS consiste em identificar cada trabécula óssea, classificando-a
como haste ou placa, e analisando sua orientação dentro do compartimento trabecular, ou
seja, se cada haste ou placa se dispõe de maneira transversal, longitudinal ou oblíqua em
relação ao eixo ósseo axial (LIU et al., 2008). À partir da caracterização de cada elemento
trabecular é possível estimar a fração do volume ósseo trabecular representada por placas
e hastes (pBV/TV e rBV/TV, respectivamente) e a razão entre essas duas medidas (razão
P-R). Da mesma forma, determina-se o número e espessura de cada tipo trabecular -
número de placas e hastes (pTb.N e rTb.N) e espessura média de placas e hastes (pTb.Th
e rTb.Th). O comprimento médio das trabéculas em haste (rTb. ℓ) e a área de superfície
média das trabéculas em placa (pTb.S) são também considerados. Além disso, a
conectividade trabecular é calculada de acordo com a morfologia de cada placa,
estimando-se a densidade de junções entre placas (P-P Junc.D), entre hastes (R-R Junc.D)
ou entre placas e hastes (P-R Junc.D). Por último, como a orientação trabecular também é
avaliada pelo método, é possível calcular a fração do volume trabecular orientado no
sentido axial (aBV/TV) (Figura 3).
Em sua descrição inicial em estudo ex vivo, os resultados de ITS foram correlacionados
com análise padrão por µCT e com parâmetros biomecânicos estimados por análise de
elementos finitos (FEA) de imagens de µCT. Resultados desses estudos indicam que
trabéculas em placa são as determinantes primárias da resistência óssea e que o aumento
da razão P-R está associado a maior rigidez2 óssea. Além disso, dentre todas as variáveis
estudadas, aBV/TV teve a melhor correlação com as medidas de competência mecânica
óssea (LIU et al., 2008).
2 do inglês, stiffness.
27
Em estudos clínicos, ITS derivada de imagens de HRpQCT revelou que mulheres na pré
menopausa com osteoporose idiopática apresentam redução preferencial de trabéculas em
placas, além de redução de aBV/TV (LIU et al., 2010). Além disso, ITS demonstrou
diferenças-chave entre o esqueleto de mulheres caucasianas e chinesa-americanas,
explicando o achado de risco reduzido de fratura em mulheres chinesas, apesar de
medidas semelhantes de aBMD (LIU et al., 2011b). Finalmente, estudo avaliando fratura
por fragilidade em mulheres na pós menopausa revelou que ITS foi capaz de distinguir
mulheres com história de fratura de controles saudáveis. Nesse estudo, fratura
osteoporótica vertebral e não vertebral foi associada a osso trabecular constituído
principalmente por hastes e redução de placas, além de redução de aBV/TV e da
conectividade trabecular (LIU et al., 2012).
Figura 3: Imagens de osso trabecular segmentado em trabéculas individuais
(A) Diferentes cores foram usadas para visualização de trabéculas individualmente; (B)
Representação de trabéculas em placa (verde) e em haste (vermelho). Imagens de tíbia
distal obtidas de mulher saudável na pós menopausa
Imagens cordialmente cedidas por Dr. Edward Guo e Bin Zhou
1.2.2- Análise de elementos finitos (FEA):
Além de fornecer dados acerca da densidade volumétrica e estrutura esquelética,
HRpQCT tem o potencial de estimar a competência biomecânica do osso. Através da
FEA de imagens de HRpQCT, determina-se rigidez óssea, parâmetro fortemente
correlacionado com resistência óssea e risco de fratura (BOUTROY et al., 2008).
28
Competência biomecânica do osso refere-se à sua capacidade de sustentar certa carga sem
sofrer fratura, e rigidez é a capacidade do material em resistir à deformação, quando uma
força lhe é aplicada. Rigidez óssea, calculada através de FEA de imagens em 3 dimensões
de HRpQCT, apresenta forte correlação com resistência óssea medida por ensaios de
compressão mecânica (PISTOIA et al., 2002; MACNEIL and BOYD, 2008). Além disso,
estudos envolvendo mulheres na pós menopausa ou homens idosos confirmam que a
rigidez óssea estimada por FEA de imagens de HRpQCT é significativamente menor em
indivíduos com história de fratura por fragilidade do que em controles sem história de
fratura (BOUTROY et al., 2008; STEIN et al., 2010; VILAYPHIOU et al., 2010; STEIN
et al., 2011; VILAYPHIOU et al., 2011).
FEA estima rigidez do osso inteiro, quando os compartimentos cortical e trabecular são
avaliados, e rigidez trabecular, quando apenas este compartimento é considerado para
análise. Outras variáveis calculadas por esse método de análise e reportadas nesse
trabalho são a porcentagem de carga suportada pelo compartimento cortical nas
superfícies distal e proximal do volume de interesse (Ctload distal e Ctload proximal).
Estas medidas levam em conta a integridade do compartimento trabecular, uma vez que
refletem a porcentagem de carga que não pode ser sustentada pelo osso trabecular e
portanto é transferida para o osso cortical. Ou seja, quanto maior o déficit estrutural do
compartimento trabecular, maior será a porcentagem de carga suportada pelo
compartimento cortical.
Apesar da HRpQCT ser capaz de fornecer informações fundamentais para avaliação da
qualidade óssea no PHPT, esse é um exame de alto custo e difícil acesso. Dessa forma,
seria de suma importância a avaliação de métodos acessíveis na prática clínica para
avaliação mais acurada do compartimento trabecular em pacientes com PHPT.
1.3- Escore de Osso Trabecular (TBS):
TBS é um novo método de avaliação de imagem desenvolvido para estimar a
microarquitetura trabecular (POTHUAUD et al., 2008). Qualquer imagem de radiografia
óssea pode ser utilizada para avaliação do TBS, mas sua principal vantagem clínica
baseia-se na possibilidade de poder ser calculado a partir de imagens de densitometria
óssea. Isso possibilita que o TBS seja estimado como complementação da avaliação de
29
aBMD, ou em exames de densitometria realizados previamente, sem necessidade de
aquisição de novas imagens. O cálculo de TBS foi incialmente desenvolvido a partir de
imagens de densitometria óssea da coluna lombar (HANS et al., 2011a) e, portanto,
estudos clínicos que avaliam a aplicabilidade do método baseiam-se em TBS da coluna
lombar. TBS calculado a partir de imagens do fêmur está em desenvolvimento, mas ainda
não disponível para fins de pesquisa clínica.
No primeiro estudo a descrever a técnica, TBS foi calculado a partir de imagens de µCT
em 2 dimensões (imagens de µCT projetadas em um plano) e correlacionado com
medidas diretas de microarquitetura trabecular por µCT (POTHUAUD et al., 2008). Os
resultados demonstraram correlação significativa entre TBS (medida indireta de
microestrutura trabecular) e BV/TV, Tb.N, Conn.D e Tb.Sp (medidas diretas por µCT).
Esse estudo utilizou peças ósseas humanas de vértebras torácicas baixas e lombares, colo
de fêmur e rádio, e as correlações foram estimadas no mesmo sítio ósseo. Em um segundo
passo para validação do método, TBS foi derivado de imagens de densitometria óssea de
vértebras lombares de cadáveres humanos (HANS et al., 2011a). TBS assim calculado
mostrou, novamente, correlação significativa com as mesmas medidas de microestrutura
trabecular por µCT descritas anteriormente. aBMD foi avaliada nas mesmas amostras
ósseas e correlacionada com TBS. Não houve correlação significativa entre aBMD e
TBS, indicando que os dois métodos, apesar de calculados a partir da mesma imagem,
traduzem características diferentes do osso. Confirmando essa teoria, algumas amostras
ósseas revelaram ter diferentes cálculos de TBS (e diferentes estruturas ósseas por µCT) a
despeito de densidades ósseas similares (HANS et al., 2011a).
TBS é calculado por software próprio (TBS iNsight Software, MedImaps, França), que
pode ser instalado no computador que gerencia o aparelho de densitometria óssea ou em
computador não conectado àquele aparelho. Em ambos os casos, arquivos não
processados contendo as imagens de coluna lombar são utilizados para análise do TBS.
TBS é expresso em valores sem unidade de medida e seu cálculo se dá a partir de
variograma da imagem bidimensional do osso trabecular. A fórmula considera as
diferenças entre os vários tons de cinza em pixels da imagem. A quantidade de pixels
com diferentes tons de cinza e o quão diferente os tons são entre si têm importância no
cálculo. O valor final de TBS dá-se pelo cálculo da inclinação da curva do variograma em
um diagrama log-log. Dessa forma, uma imagem com vários tons de cinza, mas com
30
pequena diferença entre os tons, resulta em valores maiores de TBS (microarquitetura
normal). Imagem com número menor de cinzas, mas com grande variação entre os tons,
gera valores baixos de TBS (microarquitetura deteriorada) (HANS et al., 2011a). TBS é
avaliado na mesma região de interesse usada para o cálculo da aBMD e o valor representa
a média dos valores encontrados de L1 a L4 (Figura 4).
Em estudos clínicos envolvendo mulheres na pós menopausa, TBS em coluna lombar foi
associado a risco de fraturas vertebrais e não vertebrais, estimando seu risco
independentemente dos valores de aBMD (POTHUAUD et al., 2009; RABIER et al.,
2010; WINZENRIETH et al., 2010; DEL RIO et al., 2012). Além disso, a combinação de
TBS com aBMD em coluna lombar aumentou a predição do risco de fratura em
comparação a cada um dos testes isoladamente. Esses achados foram confirmados pelo
Estudo de Manitoba, que avaliou mais de 29.000 mulheres na pós-menopausa no Canadá
(HANS et al., 2011b). Recentemente, Boutroy et al mostraram que além de estimar
fraturas osteoporóticas tão bem quanto aBMD de coluna lombar, TBS foi capaz de
identificar um subgrupo de mulheres não-osteoporóticas com alto risco de fratura
(BOUTROY et al., 2012).
Apesar de não haver consenso acerca de valores de TBS considerados alterados, alguns
autores estudaram o valor de 1,20 como possível limite inferior da normalidade (LAMY
et al., 2012; POPP et al., 2012; VASIC et al., 2012). Esses estudos foram publicados em
forma de resumos em anais de congressos, e avaliaram apenas mulheres na pós
menopausa. Os resultados demonstram que o achado de T-score ≤ -2,5 por DXA em
qualquer sítio ósseo ou TBS < 1,20 em coluna lombar, identificou uma proporção
significativamente maior de mulheres com história de fraturas por fragilidade que o
achado isolado de T-score ≤ -2,5. De forma similar, em mulheres não osteoporóticas com
TBS < 1,209, a incidência de fraturas por fragilidade foi significativamente maior que no
grupo com valores de TBS acima desse limite (BOUTROY et al., 2012). Quando as
mulheres participantes do Estudo de Manitoba foram estratificadas em tercis de acordo
com valores de TBS, os valores encontrados como limite entre os 3 grupos foram 1,20 e
1,35 (comunicação pessoal). Nesse estudo, o tercil de mulheres com menores valores
TBS tiveram maior risco de fratura osteoporótica do que as mulheres do terço médio ou
superior (HANS et al., 2011b). Baseado nesses estudos, os seguintes pontos de corte
31
foram sugeridos para classificação de TBS em mulheres na pós menopausa: TBS≤1,20=
microarquitetura degradada; TBS entre 1,20 e 1,35= microarquitetura parcialmente
degradada; TBS ≥1,35= microarquitetura normal.
Figura 4: Princípios do escore de osso trabecular
Adaptado de (POTHUAUD et al., 2008; HANS et al., 2011a)
TBS= Escore de osso trabecular
Figura cordialmente cedida por Dr. Didier Hans
O presente estudo consiste na avaliação óssea através de HRpQCT e TBS de mulheres na
pós menopausa com diagnóstico estabelecido de PHPT. Além das medidas usuais
fornecidas pela técnica de HRpQCT, ITS e FEA foram realizadas para avaliação mais
detalhada do compartimento ósseo trabecular e da competência biomecânica do
esqueleto. Os resultados foram comparados aos de 120 mulheres saudáveis da mesma
faixa-etária e estado pós menopausal. TBS foi estimado em um subgrupo de mulheres
com PHPT e correlacionado com medidas por HRpQCT.
32
2- OBJETIVOS:
2.1- Artigo 1:
Determinar, através de HRpQCT, geometria óssea, densidade volumétrica e índices
microestruturais dos compartimentos cortical e trabecular em mulheres na pós-menopausa
com PHPT, comparando-as com um grupo controle.
Investigar a competência biomecânica do osso através de FEA de imagens de HRpQCT e,
pela primeira vez em pacientes com PHPT, analisar as imagens de HRpQCT através da
técnica de ITS para avaliação mais detalhada do compartimento ósseo trabecular nessa
doença.
2.2- Artigo 2:
Avaliar a correlação entre TBS e medidas por HRpQCT em pacientes com PHPT.
33
3- RESULTADOS:
3.1- Artigo 1:
Primary Hyperparathyroidism is Associated with Abnormal Cortical and Trabecular
Microstructure and Reduced Bone Stiffness in Postmenopausal Women
Artigo aceito para publicação no “Journal of Bone and Mineral Research” em 26 de
novembro de 2012.
34
Primary Hyperparathyroidism is Associated with Abnormal Cortical and
Trabecular Microstructure and Reduced Bone Stiffness in Postmenopausal
Women
Emily M Stein1*, Barbara C Silva1,3*, Stephanie Boutroy1, Bin Zhou2, Ji Wang2, Julia
Udesky1, Chiyuan Zhang1, Donald J McMahon1, Megan Romano1,
Elzbieta Dworakowski1, Aline G. Costa1, Natalie Cusano1, Dinaz Irani1, Serge Cremers1,
Elizabeth Shane1, X Edward Guo2, John P Bilezikian1#
* These authors contributed equally to this work 1- Metabolic Bone Diseases Unit, Division of Endocrinology, Department of Medicine, College of
Physicians and Surgeons, Columbia University, New York, NY, USA
2- Bone Bioengineering Laboratory, Department of Biomedical Engineering, Columbia University,
New York, NY, USA
3- College of Medicine of Federal University of Minas Gerais, Belo Horizonte, Brazil
# Correspondence to:
John P. Bilezikian. M.D.
College of Physicians and Surgeons
630 W, 168th Street, New York, NY 10032, USA
Phone: 212.305.6257
Fax: 212.305.6486
e-mail: [email protected]
35
Abstract:
Typically, in the milder form of primary hyperparathyroidism (PHPT), seen in most
countries now, bone density by DXA and detailed analyses of iliac crest bone biopsies by
histomorphometry and µCT show detrimental effects in cortical bone, whereas the
trabecular site (lumbar spine by DXA) and the trabecular compartment (by bone biopsy)
appear to be relatively well preserved. Despite these findings, fracture risk at both
vertebral and non-vertebral sites is increased in PHPT. Emerging technologies, such as
high-resolution peripheral quantitative computed tomography (HRpQCT), may provide
additional insight into microstructural features at sites such as the forearm and tibia that
have heretofore not been easily accessible. Using HRpQCT, we determined cortical and
trabecular microstructure at the radius and tibia in 51 postmenopausal women with PHPT
and 120 controls. Individual trabecula segmentation (ITS) and micro finite element (µFE)
analyses of the HRpQCT images were also performed to further understand how the
abnormalities seen by HRpQCT might translate into effects on bone strength. Women
with PHPT showed, at both sites, decreased volumetric densities at trabecular and cortical
compartments, thinner cortices, and more widely spaced and heterogeneously distributed
trabeculae. At the radius, trabeculae were thinner and fewer in PHPT. The radius was
affected to a greater extent in the trabecular compartment than the tibia. ITS analyses
revealed, at both sites, that plate-like trabeculae were depleted, with a resultant reduction
in the plate/rod ratio. Microarchitectural abnormalities were evident by decreased plate-
rod and plate-plate junctions at the radius and tibia, and rod-rod junctions at the radius.
These trabecular and cortical abnormalities resulted in decreased whole bone stiffness and
trabecular stiffness. These results provide evidence that in PHPT, microstructural
abnormalities are pervasive and not limited to the cortical compartment. They may help
to account for increased global fracture risk in PHPT.
Key words: Primary hyperparathyroidism, high-resolution peripheral quantitative
computed tomography, individual trabecula segmentation, finite element analysis,
fracture risk.
36
Introduction
Primary hyperparathyroidism (PHPT), a common endocrine disorder, is characterized
primarily by hypercalcemia and elevated levels of parathyroid hormone (PTH). Although
the disease harbors a potential for extensive destruction of the skeleton, and commonly
presented in this way during the first several decades of its description (1), asymptomatic
PHPT has become the predominant form of the disease since the 1970s (2-4). Typically,
in this milder form of PHPT, bone density by dual energy X-ray absorptiometry (DXA) is
reduced with a proclivity for greatest reduction at the 1/3 radius, a site of cortical bone.
By DXA, the lumbar spine, a site comprised predominantly of cancellous bone, tends to
be preserved and similar to age-matched control subjects (5). Histomorphometric and
micro-computed tomography (µCT) analyses of iliac crest bone biopsies have confirmed
these DXA results by specific measurements of cortical and trabecular compartments.
Cortical width is reduced and cortical porosity is increased. Trabecular bone volume is
above average while trabecular number, connectivity and separation are preserved (6-10).
However, these results are not consistent with evidence from many different studies
demonstrating increased fracture risk at both vertebral and non-vertebral sites in PHPT
(11-14). While the fracture data are still incomplete, the likelihood of overall increased
fracture risk would argue, on the one hand, that DXA is not accurately depicting
microstructure of bone due to its limited resolving power, and on the other hand, that the
bone biopsy data from the iliac crest, in which the microstructure of bone is easily
depicted, is not representative of load-bearing sites or other sites that are predisposed to
fracture. Occasional reports of reduced trabecular bone density in PHPT (15, 16) argue
that trabecular bone, clearly a potential target in severe disease, might also be affected in
more mild disease and that more highly resolved technologies that can be applied to sites
of loaded and unloaded bone would be revealing.
High resolution, noninvasive imaging methods, enabling in vivo assessment of cortical
and trabecular bone microarchitecture and biomechanical competence, could provide
additional insight into compartment-specific (trabecular vs cortical) effects of PTH in
PHPT and be more pertinent to the clinical discussion of fracture risk in PHPT. To this
end, High Resolution peripheral Quantitative Computed Tomography (HRpQCT), a non-
invasive technique has sufficient resolution (voxel size, 82 µm) to quantitate trabecular
and cortical microstructure that previously could be assessed only in bone biopsy
samples. Moreover, HRpQCT has been developed to visualize the microstructure of the
37
distal radius, an unloaded site, and the distal tibia, a loaded site. Strong correlations
between microarchitecture assessed by HRpQCT and histomorphometry or µCT at the
same bony regions have been demonstrated (17, 18). This technology further
distinguishes subjects who have sustained vertebral and non-vertebral fractures from
normal controls (19-23), and detects changes in bone microstructure related to aging or
other causes of bone loss (24-26). Recently, Hansen et al observed, by HRpQCT, altered
trabecular and cortical structure at the radius in PHPT, and improvement in volumetric
density and bone microarchitecture following parathyroidectomy (27, 28). This report
supports the idea that if sites more relevant to fracture risk in PHPT are measured with
highly resolved technologies, abnormalities in trabecular bone can be observed.
In addition to assessing microstructure, HRpQCT images can be used to measure
mechanical competence of bone by microstructural finite-element analysis (µFEA) (29).
Recent advances have demonstrated that individual trabecula segmentation (ITS)-based
morphologic analysis of HRpQCT images can provide even more specific information
about trabecular bone microarchitecture. ITS resolves the HRpQCT image into individual
trabeculae, characterizing trabecular elements as either plates or rods. Plate-like
trabeculae are the primary determinants of bone strength; a higher plate/rod ratio is
associated with greater strength (30, 31). µFE and ITS analyses of HRpQCT images
distinguish among individuals with and without osteoporosis and fragility fractures,
independent of DXA measurements (23, 32-35). ITS analyses of HRpQCT images have
also demonstrated key differences between the Caucasian American and Chinese
American skeleton, helping to account for reduced fracture risk in Chinese women
despite similar bone mineral densities (36).
In this study, we have utilized HRpQCT to determine microstructural indices of cortical
and trabecular compartments at the radius and tibia in 51 postmenopausal women with
PHPT and 120 normal controls. We have also utilized µFE and, for the first time, ITS
analyses of HRpQCT images to assess trabecular morphology and bone compartment-
specific mechanical competence in PHPT. The results of this study provide new insights
into bone quality in postmenopausal women with PHPT.
38
Patients and Methods
Study Subjects:
51 postmenopausal community-dwelling women, with well-characterized PHPT (elevated
serum calcium and abnormal PTH levels) were recruited from Columbia University
Medical Center (CUMC) in New York. The 120 control individuals were healthy
postmenopausal women selected independently of their areal bone mineral density by
DXA, also recruited from CUMC by advertisement, self or physician referral. All control
subjects had normal serum calcium levels and no history of PHPT or low trauma fracture.
Exclusion criteria included significant use of glucocorticoids within the past 2 years,
history of Cushing’s syndrome, uncontrolled thyroid disease, malabsorption syndrome,
significant liver disease, creatinine clearance < 30 mL/min, and any chronic disorders of
mineral metabolism such as Paget’s disease or osteogenesis imperfecta. Use of
bisphosphonates, raloxifene, and hormone replacement therapy (HRT) were not an
exclusionary criterion. Women were considered postmenopausal if they had not had a
menstrual period for over 1 year.
The study was approved by the Institutional Review Board of Columbia University
Medical Center, and all subjects gave written informed consent.
Dual-energy X-ray absorptiometry (DXA):
Areal bone mineral density (aBMD) was measured at the lumbar spine (L1–L4), total hip,
femoral neck, and nondominant forearm [ultradistal (UD radius) and one-third radius (1/3
radius)] by DXA (Hologic 4500A; Hologic Inc., Bedford, MA, USA). Short term, in vivo
precision error was 0.5% for L1–L4, 1.5% for total hip and femoral neck, and 1% for the
forearm.
HRpQCT:
The nondominant distal radius and tibia were measured using the HRpQCT system
(Xtreme CT; Scanco Medical AG, Brüttisellen, Switzerland) at CUMC. This device uses
a 2D detector array and a 0.08-mm point-focus X-ray tube enabling the simultaneous
acquisition of a stack of a parallel CT slices with a nominal resolution (voxel size) of
82µm. The following settings were used: effective energy of 60kVp, x-ray tube current of
900µA, and image matrix size of 1,536 x 1,536.
39
An antero-posterior scout view was used to define the measurement region. A reference
line was manually placed at the end plate of the radius and tibia. A stack of 110 parallel
CT slices was acquired (distal to proximal), with the first slice being 9.5 mm proximal to
the reference line at the radius and 22.5 mm proximal to the reference line at the tibia. At
each skeletal site, a 3D image of approximately 9 mm in the axial direction was obtained.
Attenuation data were converted to equivalent hydroxyapatite (HA) densities. For quality
control, the manufacturer phantom was scanned daily.
Image analysis has been described and validated (17, 24, 25, 37). Briefly, the entire
volume of interest is automatically separated into cortical and trabecular regions by using
a threshold-based algorithm. Mean cortical thickness (Ct.Th) is defined as the mean
cortical volume divided by the outer bone surface. Cortical and trabecular bone densities
(Ct.vBDM and Tb.vBMD) are defined as the average bone density within the cortical or
trabecular volume of interest, respectively. Trabecular bone volume (BV/TV) is derived
from Tb.vBMD assuming that fully mineralized bone has the density of 1,200 mg
hydroxyapatite (HA) per cubic centimeter (BV/TV (%)=100x (Tb.vBMD/1,200). Since
the nominal spatial resolution of the XtremeCT (82 µm) is in the range of trabecular
dimensions, visualization of individual trabeculae is limited. Therefore, measurements of
trabecular microstructure are assessed using a thickness-independent algorithm. To this
end, trabecular elements are identified by a mid-axis transformation method and the
distance between them is assessed by the distance-transform method. Trabecular number
(Tb.N) is taken as the inverse of the mean spacing of the mid-axes. Trabecular thickness
(Tb.Th) and trabecular separation (Tb.Sp) are then derived from BV/TV and Tb.N using
standard methods of histomorphometry, i.e., Tb.Th=(BV/TV)/Tb.N and
Tb.Sp=(1−BV/TV)/Tb.N. Distance transformation techniques also enable the calculation
of intra-individual distribution of separation (Tb.Sp.SD), quantified by the SD of the
separation, a parameter reflecting the heterogeneity of the trabecular network.
ITS-based morphological analyses of HRpQCT images:
The trabecular bone compartment was manually extracted from the cortex of each
HRpQCT image of the distal radius and distal tibia. All trabecular bone images were then
subjected to ITS-based morphological analyses. A complete volumetric decomposition
technique was applied to segment the trabecular network into individual plates and rods
(30). Briefly, digital topological analysis (DTA)-based skeletonization is performed to
40
transform the trabecular bone image into a schematic comprised of surfaces and curves
skeleton. The topology (i.e, connectivity, tunnels, and cavities), as well as the rod and
plate morphology of the trabecular microarchitecture, are preserved. Each skeletal voxel
is uniquely classified as either a surface (plate) or a curve (rod) type. Using an iterative
reconstruction method, each bone voxel of the original image is classified as belonging to
either type of trabecula. ITS parameters of scale evaluate plate and rod bone volume
fraction (pBV/TV and rBV/TV), plate and rod number density (pTb.N and rTb.N, 1/mm),
plate and rod thickness (pTb.Th and rTb.Th, mm), plate surface area (pTb.S, mm2), and
rod length (rTb.ℓ, mm). Plate-to-rod ratio (P-R ratio) was defined as plate bone volume
divided by rod bone volume. Trabecular network connectivity is characterized by plate–
plate, plate–rod, and rod–rod junction density (P-P, P-R, and R-R Junc.D, 1/mm3),
calculated as the total junctions between trabecular plates and rods normalized by the
bulk volume. Lastly, the orientation of trabecular bone network is characterized by axial
bone volume fraction (aBV/TV), defined as axially aligned bone volume divided by the
bulk volume.
µFEA of HRpQCT images:
Whole bone and trabecular HRpQCT images of the radius and tibia were converted into
micro finite element models. µFEA was then performed to estimate whole bone and
trabecular stiffness. For each µFE model, a uniaxial compression test was performed with
displacement equivalent to 1% apparent strain to calculate stiffness. Bone tissue was
assumed to have an isotropic linear material property with Young’s modulus 15 GPa and
Poisson’s ratio 0.3. Whole bone stiffness, defined as reaction force divided by the applied
displacement, characterizes the mechanical competence of both cortical and trabecular
compartments and is closely related to whole bone strength (38). Similarly, trabecular
bone stiffness characterizes the mechanical competence of the trabecular bone
compartment. Percent load carried by the cortical compartment at the distal and proximal
surface of bone segments was also calculated.
Biochemical analysis
Blood samples were drawn in a fasting state. Serum total calcium and albumin were
analyzed using standard methods (Quest Diagnostics, Madison, NJ, USA). Calcium
values were corrected for low albumin (albumin < 4 g/dL). In patients with PHPT, intact
PTH was measured by immunoradiometric assay (Scantibodies, Santee, CA, USA) in the
41
Bone Marker Laboratory of the Metabolic Bone Diseases Program at CUMC. The normal
range was 14 to 66 pg/mL, and the precision inter- and intra-assay coefficients were
below 7% and 5%, respectively.
Statistical Analysis:
Descriptive statistics and group comparisons are expressed as mean ± SEM. Differences
in continuous variables between cases and controls were assessed by Student’s t-test.
Dichotomous variables were compared using the chi-square test. Comparisons of percent
difference in HRpQCT, ITS and mechanical measurements between cases and controls at
the radius and tibia were calculated and then assessed by Student’s t-test for paired
samples. Since serum PTH levels and BMI did not follow a normal distribution, the
Spearman correlation test was used to estimate their correlation with HRpQCT indices.
Finally, comparisons of correlations between groups and between sites were examined by
Fisher’s Z transformation (39). All statistical tests were performed at the two-sided 0.05-
level of significance. Statistical analysis was performed using SAS, version 9.2 (SAS
Institute, Inc., Cary, NC, USA).
42
Results
Baseline clinical, biochemical and densitometric data of the 51 postmenopausal women
with PHPT and 120 controls are described in Table 1. Case and control subjects did not
differ on the basis of age, body weight, height, BMI, years since menopause, and current
use of HRT and raloxifene. Bisphosphonate use was significantly greater among patients.
As expected, serum calcium levels were higher in the PHPT group. The majority of PHPT
patients (77%) were asymptomatic. Only 12 subjects had nephrolithiasis (n=6) and/or
fragility fracture (n=8).
aBMD by DXA:
aBMD was significantly lower in PHPT subjects than in controls at the total hip, femoral
neck, and UD radius. Mean aBMD by DXA was similar in PHPT and controls at the
lumbar spine and 1/3 radius (Table 1). In the PHPT group, the lumbar spine and total hip
T-scores were higher than the T-scores at the femoral neck and both radial sites (Table 1).
HRpQCT standard analysis:
As shown in Table 2 and representative 3D images of the radius in Figure 1, PHPT was
associated with reduced volumetric densities (vBMD), and altered cortical and trabecular
microarchitecture as assessed by HRpQCT.
At the radius and tibia, total bone area was not significantly different from control
subjects. Total vBMD was significantly lower in PHPT at the radius (-19%) and tibia (-
13%). Ct.vBMD and Ct.Th. were 6% and 18% lower at the radius, and 7% and 15%
lower at the tibia in PHPT vs control subjects (p<.001 for all). Significant reductions of
Tb.vBMD at the radius (-23%) and tibia (-11%) were also observed in PHPT (p<0.01). At
the radius, trabecular microarchitectural indices in PHPT were different from controls (p<
0.05) with lower Tb.N (-13%), Tb.Th (-12%) and increased Tb.Sp (+32%). At the tibia,
there were no significant differences in Tb.N and Tb.Th between the two groups, but
Tb.Sp was higher in PHPT subjects (+16%) (Table 2 and Figure 2).
As shown in Figure 2, compared to tibial measurements, the percentage differences
between cases and controls were more pronounced at the radius for total vBMD
(p=0.006), Tb.vBMD (p=0.0004), and Tb.N (p=0.02).
43
ITS-analysis of HRpQCT images:
ITS analysis of the trabecular compartment revealed key microstructural differences at
the radius, and, to a lesser extent, at the tibia in PHPT (Table 3 and Figure 3).
At the radius, plate and rod bone volume fraction (pBV/TV, rBV/TV), plate and rod
trabecular number (pTb.N, rTb.N), and plate-rod ratio (P-R ratio) were 31%, 13%, 11%,
5% and 22% lower in PHPT vs. controls, respectively (p<0.01). At the tibia, pBV/TV,
pTb.N and P-R ratio were 20%, 5% and 19% lower in PHPT patients, respectively
(p<0.01), whereas no significant differences for tibial rBV/TV and rTb.N were found.
The axial bone volume fraction (aBV/TV) was significantly reduced at the radius (-25%),
and at the tibia (-16%) in PHPT vs controls. At the radius, rod-to-rod, plate-to-rod and
plate-to-plate junction densities (R-R, P-R, and P-P JuncD) were significantly lower in
PHPT at 13%, 26%, and 30%, respectively. Similarly, there was a significant decrease in
P-R (-9%), and P-P JuncD (-15%) at the tibia in patients with PHPT.
The percentage-differences between cases and controls were again more pronounced at
the radius as compared to the tibia for virtually all ITS parameters (Figure 3).
µFEA of HRpQCT images:
The differences in volumetric density, cortical and trabecular microstructure were
associated with significant changes in bone mechanical properties (Table 3 and Figure 3).
Trabecular stiffness was 46% and 18% lower in the PHPT than in the control group at the
radius and tibia, respectively. Whole bone stiffness was reduced by 22% at the radius, and
10% at the tibia. At the radius, the percentage of load carried by the cortical compartment
was greater in PHPT, at both distal and proximal surfaces, at the radius (Figure 3). The
increased percentage of load carried by the cortical compartment observed in PHPT may
be explained by the abnormal trabecular microstructure, resulting in a shift in load
distribution to the cortical compartment at the radius. At the tibia, since the trabecular
abnormalities, although present, were not as great as at the radius, shift in load bearing to
the cortical compartment did not differ statistically between groups.
As shown in Figure 3, percentage differences between cases and controls were greater at
the radius than at the tibia for trabecular and whole bone stiffness, and for the percentage
of load carried by the cortical compartment at the distal surface.
44
Analysis of the subgroup not on bisphosphonate therapy:
Since the use of bisphosphonate was significantly greater among PHPT patients, we
verified whether or not bisphosphonate use would change our outcomes. The comparison
between cases and controls not currently on bisphosphonate therapy shows reduced
volumetric densities, deterioration of microarchitecture by standard HRpQCT and ITS,
and decreased bone strength in PHPT patients (data not shown). These results are similar
to the ones observed when the whole group was analyzed, indicating that bisphosphonate
use did not influence any of the outcome measures.
Relationships between PTH and BMI with Cortical and Trabecular indices:
Among subjects with PHPT, serum PTH levels were inversely correlated with total
vBMD, Tb.vBMD, and Tb.Th at the radius (r=-0.300, -0.326, -0.407, respectively;
p<0.05 for all). At the tibia, significant negative correlations were found between serum
PTH and total vBMD (r=-0.354), Ct.vBMD (r=-0.352), and Ct.Th (r=-0.350) (Figure 4).
Similarly, at the radius, serum PTH levels correlated inversely and significantly with all
ITS and mechanical parameters, except for rTb.N, pTb.S and R-R JuncD. At the tibia,
whole bone stiffness, pBV/TV, aBV/TV, pTb.N, rTb.Th, P-P and P-R Junc.D were
inversely correlated with serum PTH (p<0.05). In contrast, serum PTH did not show
significant correlations with aBMD by DXA at any site (data not shown). Serum calcium
was also not correlated with aBMD, vBMD, microstructural parameters or bone stiffness
(data not shown).
To evaluate the influence of mechanical loading on trabecular and cortical bone
compartments, we examined the relationships between BMI with HRpQCT-derived
parameters at the tibia, a load bearing bone, in cases and controls and at the radius, a non-
load bearing bone. At the tibia, cortical parameters were positively correlated with BMI
in control subjects, whereas in the PHPT group, the correlation between Ct.vBMD and
Ct.Th with BMI was not significant. Conversely, correlation coefficients between BMI
and HRpQCT for trabecular indices such as Tb vBMD, Tb.N, and Tb.Sp were greater in
PHPT (Table 4). The correlation coefficient between BMI and Tb.N at the tibia was
significantly higher in the PHPT group (p=0.02 for comparison of correlations). The
comparison of these correlations between cases and controls at the radial site did not
show such major differences. Correlation coefficients between BMI and cortical
HRpQCT indices, in comparison to the radial site, were greater at the tibia in the control
45
group (Table 4). In PHPT, these correlations showed greater dependence upon BMI at the
tibia than at the radius with regard to the following indices: Tb.N, Tb.Sp, Tb.Sp.SD, and
Tb.vBMD (Table 4).
46
Discussion
The results of this study signal a major change in analytical approaches to bone strength
in PHPT. Previously, DXA and histomorphometric analyses of the iliac crest bone biopsy
gave important information but each was limited in either its resolving power (DXA) or
in the fact that the iliac crest is not clearly representative of bones at risk in this disease
for fracture. With HRpQCT, questions relevant to fracture risk in PHPT can be analyzed
with regard to skeletal microstructure and, further, with ITS, a novel approach that allows
for specific assignments of microarchitecture based on topological orientation and type of
trabeculae. In addition, compartmental analyses of cortical and trabecular bone at a
loaded (tibia) or unloaded (radius) site provide new insights into how in PHPT, a disorder
of chronic PTH excess, compromised structural integrity is not limited to the cortical
skeleton.
At the radius, by HRpQCT, women with PHPT have lower total, cortical, and trabecular
densities along with a thinner cortex. Trabecular microarchitecture is affected with fewer,
thinner, more widely and heterogeneously distributed trabeculae. At the tibia, these
changes are not as widespread but reductions in vBMDs and cortical thickness are
evident, along with more widely and heterogeneously distributed trabeculae. In contrast
to the radius, no abnormalities at the tibia were appreciated in trabecular number or
trabecular thickness.
The catabolic effects of PTH on both cortical and trabecular bone compartments reported
here have been observed by peripheral quantitative computed tomography (pQCT) in
PHPT (15, 40). While qualitatively similar to our observations, the resolution of pQCT is
poor relative to HRpQCT (voxel size: 500-590 µm vs 82 µm) and thus does not permit a
detailed compartmental analysis of cortical and trabecular bone. Applying HRpQCT,
Hansen et al. (27) recently did show changes at the radius in 26 pre and postmenopausal
women with PHPT. These investigators, however, were not able to appreciate significant
differences at the tibia, perhaps because of the small number of subjects in their study
(only 23 postmenopausal women) and less dramatic changes at the tibial site.
This report provides further insights, not explored previously, into trabecular
microstructure at the individual trabecula level by ITS analysis of the HRpQCT images.
ITS analysis, developed by Guo and his associates, has been validated for assessing
47
trabecular microarchitecture by significant concordance with µCT (41). In PHPT, we
found that plate-like trabeculae are depleted, and that the P-R ratio is reduced. This
topological disturbance in microstructure leads to a trabecular network that is abnormal in
plate-rod and plate-plate junctions at the radius and tibia, and rod-rod junctions at the
radius. With relatively more rods than plates in the trabecular network, µFE analysis
indicates that bone strength is compromised in terms of whole bone and trabecular
stiffness. While both radial and tibial sites are compromised, greater deficits are seen in
the distal radius. Such distortions lead to a significant increase in the load carried by the
cortical compartment in the radius. These changes highlight another insight gleaned from
this report, namely that with abnormal cortical structure in PHPT, the load carried by this
compartment is disproportionately distributed from the trabecular compartment because it
too is compromised.
Based upon these findings, the pattern of bone loss in PHPT shown in many studies by
DXA needs to be reexamined. The discordant observations of preserved lumbar spine
aBMD by DXA and trabecular microstructure abnormalities by HRpQCT could be
explained by the DXA technology. As a 2D measure, DXA is influenced by bone size.
The increased cross sectional area in patients with PHPT observed by us an others (40,
42-44), which might be a compensatory mechanism or a direct effect of PTH, could have
accounted for the apparent preserved aBMD at the lumbar spine. Thus, the preservation
of lumbar spine bone density by DXA in PHPT illustrates the uncertainty of this
technology if geometric or microstructural abnormalities are present. Even the
microstructural data by histomorphometric analysis of iliac crest bone biopsies in PHPT
needs to be reexamined in light of these new data. By histomorphometry of bone biopsies
from iliac crest, trabecular bone in postmenopausal women with PHPT is preserved as
documented by no abnormalities in trabecular number, connectivity, or separation (5-8,
10, 45). In fact, µCT analysis of bone biopsy specimens showed that trabecular bone
volume in postmenopausal women with PHPT is increased (9). It is becoming increasing
clear, however, that the iliac crest might not be an ideally representative site of the
peripheral skeleton. In fact, Cohen et al (46) have found modest or no correlations
between microarchitecture parameters as assessed by HRpQCT of radius and tibia and
histomorphometry and µCT of iliac crest biopsies. Since previous studies have shown
strong correlations between microarchitecture assessed by HRpQCT and
histomorphometry or µCT at the same bony regions (17, 18), site-to-site differences are
48
likely to contribute to the weak correlations observed in the study of Cohen et al (46).
Even at peripheral sites, such as the radius and tibia, there are differences to be observed.
The differences may well be due to the extent to which a site is loaded (tibia) or unloaded
(radius). Deficits in skeletal microstructure were less pronounced at the tibia in other
studies (19, 23), perhaps due to positive effects of mechanical loading at this site. We
observed greater effects of loading on the cortical bone in normal postmenopausal women
than in PHPT patients, as observed by higher correlation coefficients between BMI and
cortical indices at the tibia in controls. In PHPT, the effect of loading was also
compartment-specific with the trabecular bone affected to a greater extent than cortical
bone. In fact, cortical parameters at the tibia were not significantly correlated with BMI,
whereas the correlation coefficients between BMI and trabecular measurements were
greater in PHPT than in controls. Further supporting the idea that mechanical loading
ameliorates catabolic actions of PTH on trabecular bone, we showed that trabecular bone
was much more profoundly affected at the distal radius than at the tibia, whereas cortical
bone was equally affected at the radius and tibia in PHPT. In addition, correlations
between PTH and HRpQCT-derived trabecular indices were significant at the radius but
not at the tibia, indicating that the negative effects of PTH are blunted at the load-bearing
tibial site. These data suggest that mechanical loading does not prevent cortical loss in
PHPT, but it may help to counteract the deleterious effects of PTH on trabecular bone.
These results provide a framework for understanding that the osteoanabolic action of
PTH is not seen in PHPT, a state of chronic PTH excess, but rather is limited to the
intermittent administration of the hormone when used as a therapeutic for osteoporosis.
These observations have implications for assessment of fracture risk in PHPT. The
HRpQCT analysis that we have conducted suggests that there is a biomechanical basis for
increased fracture risk in this disease. While studies of fracture risk in PHPT are by no
means definitive, the cumulative experience suggests that both the central (trabecular)
and peripheral (cortical) skeleton are at risk. If HRpQCT analyses correlate with fracture
risk, then the clinical observations of fracture risk in PHPT and the detailed
microstructural observations of this study are consistent. In fact, previous studies have
correlated HRpQCT-based abnormalities in skeletal microstructure with fracture risk in
postmenopausal women (19-23, 34, 35). Similarly, reductions in plate and rod BV/TV,
plate and rod trabecular number, less axially aligned trabecular network, and reduced
49
connectivity between plate-plate, and plate-rod like trabeculae by ITS-analysis of
HRpQCT scans, all of which have been demonstrated in this study, have been described
in postmenopausal women with fragility fractures (32). In several of these studies,
deterioration of skeletal microstructure could distinguish between women with and
without fractures even after adjusting for aBMD or T-score by DXA (19, 23, 32).
Moreover, in the study by Pistoia et al (47), the correlation between bone strength
(mechanically measured) and failure load predicted by 3DpQCT-based µFEA was
stronger than its correlation with aBMD assessed by DXA. Our subjects with PHPT have
similar deficiencies in skeletal microstructure and stiffness to those observed in
postmenopausal women with fractures. Thus, the data provide a biomechanical
mechanism to account for increased fracture risk in PHPT.
This study has some limitations. Only postmenopausal women were studied so that it is
not known whether the results are applicable to men or premenopausal women with
PHPT. Our study was not designed to assess differences between patients with or without
fractures within the PHPT group. It remains to be seen whether these abnormalities will
be appreciated to a greater extent among those who have sustained a fracture. The cross-
sectional design prevented us from investigating whether or not the microstructural
abnormalities at cortical and tibial sites as measured by HRpQCT will worsen over time
in patients with PHPT and, if so, whether there are predictive features to this expectation.
We have not yet studied subjects after parathyroidectomy in comparison to these
preoperative, baseline data. HRpQCT is an analytical device that measures only
peripheral sites, and, thus, it is possible that our findings will not reflect central sites such
as the lumbar spine. This is unlikely in view of the recent study by Liu et al (48) in which
volumetric density, bone microstructure and mechanical properties of peripheral sites as
determined by HRpQCT correlated significantly with mechanical competence of the
spine and hip.
Despite these limitations, our study has important strengths. The analytical power of
HRpQCT applied to sites of great relevance to fracture risk is noteworthy. The added
analytical power of ITS with µFEA provides another dimension not previously examined
in this disease. The data provide greater understanding of biomechanical compromise in
PHPT, helping to resolve a previous conundrum in which preserved trabecular bone by
DXA or by histomorphometric studies of the iliac crest were not consistent with the
50
clinical observations of increased fracture risk in PHPT. Further studies are likely to
provide even greater insights into microstructural features of bone in PHPT and permit
greater understanding of fracture risk in this disease.
Disclosures:
The authors state that they have no conflicts of interest
Acknowledgments:
All authors met guidelines for authorship: Study design (JPB, DJM), Study conduct
(EMS, BCS, JPB, JU, MR, NC, DI, AGC, ED, SC), Data analysis (BCS, CZ, DM, BZ,
JW), Data interpretation (BCS, EMS, JPB, ES, NC, XEG, SB), Drafting the manuscript
(BCS and JPB), Revising manuscript content (all authors), Approving final version of
manuscript (all authors). Supported in part by the following NIH grants: DK32333, UL1
RR024156, K24 AR052665 (E. Shane), AR 055068, AR058004, AR051376, K23 DK
084337 (EM. Stein), K23 DK 095944 (N Cusano), and the Brazilian National Council of
Technological and Scientific Development – CNPq (BC Silva).
51
Figures:
Figure 1: Representative HRpQCT images of the distal radius of PHPT (A) and control
(B) subjects
52
Figure 2: Comparison of HRpQCT results at the distal radius and tibia in PHPT and
control groups
* Represent significant differences between groups (p<0.05)
# Represent significant differences for comparisons of the percentage difference between
radius and tibia (p<0.05)
Total vBMD= total volumetric bone mineral density; Ct.vBMD= cortical volumetric bone
mineral density; Ct.Th= cortical thickness, Tb.vBMD= trabecular volumetric bone
mineral density; Tb.N= trabecular number; Tb.Th= trabecular thickness; Tb.Sp=
trabecular separation; Tb.Sp.SD= trabecular distribution
53
Figure 3: Comparison of the ITS and µFEA results at the distal radius and tibia in PHPT
and control groups
* Represent significant differences between the groups (p<0.05)
# Represent significant differences for comparisons of the percentage difference between
radius and tibia (p<0.05)
pBV/TV= plate bone volume fraction; rBV/TV= rod bone volume fraction; P-R ratio=
plate-to-rod ratio; aBV/TV= axial bone volume fraction; pTb.N= plate number density;
rTb.N= rod number density; pTb.Th= plate thickness; rTb.Th= rod thickness; pTb.S=
plate surface area; rTb.ℓ= rod length; R-R Junc.D= rod–rod junction density; P-R
Junc.D= plate–rod junction density; P-P Junc.D= plate–plate junction density, Trab.
Stiffness= trabecular stiffness; Stiffness= whole bone stiffness; Ctload distal= cortical
load at distal surface; and Ctload proximal= cortical load at proximal surface
54
Figure 4: Correlations between PTH and Tb.vBMD (A) and Tb.Th (B) at the radius, and
Ct.vBMD (C) and Ct.Th (D) at the tibia, in the PHPT group. Ct.vBMD and Ct.Th at the
radius, and Tb.vBMD and Tb.Th at the tibia were not significantly correlated with PTH.
PTH= parathyroid hormone; Tb.vBMD= trabecular volumetric bone mineral density;
Tb.Th= trabecular thickness; Ct.vBMD= cortical volumetric bone mineral density; and
Ct.Th= cortical thickness.
55
Table 1: Baseline clinical, biochemical and densitometric data of 51 PHPT and 120
control subjects:
Characteristics PHPT (n=51) Controls (n=120) p-value
Age (years) 70 ± 1 68 ± 1 .20
Weight (kg) 67 ± 2 69 .37
Height (cm) 160 ± 1 160 ± 1 .94
BMI (kg/cm2) 26.0 ± 0.9 26.8 ± 0.6 .42
Years since menopause 18 ± 2 19 ± 1 .86
Years since diagnosis 8.4 ± 1.1 NA
Current medication use (%):
Bisphosphonate 20 3 <.0001
HRT 10 6 .66
Raloxifene 6 4 .94
Serum total calcium (mg/dL) 10.6 ± 0.1 9.5 ± 0.0 <.0001
PTH (pg/mL) 76 ± 6 ND
L1-L4 BMD (g/cm2) 0.915 ± 0.024 0.931 ± 0.013 .56
T-score -1.1 ± 0.2 -1.2 ± 0.1 .74
Total hip BMD (g/cm2) 0.758 ± 0.019 0.812 ± 0.019 .015
T-score -1.5 ± 0.2 -1.1 ± 0.1 .034
Femoral neck BMD (g/cm2) 0.642 ± 0.017 0.668 ± 0.009 .03
T-score -1.9 ± 0.2 -1.7 ± 0.1 .23
1/3 radius BMD (g/cm2) 0.589 ± 0.014 0.610 ± 0.007 .16
T-score -1.8 ± 0.2 -1.4 ± 0.1 .15
UD radius BMD (g/cm2) 0.338 ± 0.011 0.379 ± 0.006 .0007
T-score -1.8 ± 0.2 -1.2 ± 0.1 .0026
NA: not applicable; ND: no data
56
Table 2: Bone geometry, density and microarchitecture by HRpQCT in PHPT patients
and controls:
HRpQCT parameters PHPT (n=51) Control (n=120) p-value
Rad
ius
Total Area (cm2) 236 ± 7 224 ± 4 .09
Total vBMD (mgHA/cm3) 241 ± 11 299 ± 7 <.0001
Ct.vBMD (mgHA/cm3) 801 ± 12 851 ± 7 .0001
Ct.Th (mm) 0.595 ± 0.026 0.722 ± 0.017 <.0001
Tb.vBMD (mgHA/cm3) 101 ± 6 131 ± 4 <.0001
Tb.N (1/mm) 1.53 ± 0.07 1.77 ± 0.03 .003
Tb.Th (mm) 0.054 ± 0.001 0.061 ± 0.001 .0001
Tb.Sp (mm) 0.711 ± 0.063 0.538 ± 0.02 .01
Tb.Sp SD (mm) 0.465 ± 0.070 0.271 ± 0.021 .01
Tibi
a
Total Area (cm2) 690 ± 16 662 ± 9 .13
Total vBMD (mgHA/cm3) 212 ± 8 245 ± 5 .0003
Ct.vBMD (mgHA/cm3) 730 ± 14 785 ± 6 .0005
Ct.Th (mm) 0.739 ± 0.040 0.874 ± 0.025 .004
Tb.vBMD (mgHA/cm3) 130 ± 5 146 ± 3 .006
Tb.N (1/mm) 1.65 ± 0.07 1.73 ± 0.03 .27
Tb.Th (mm) 0.067 ± 0.002 0.071 ± 0.001 .13
Tb.Sp (mm) 0.613 ± 0.042 0.529 ± 0.011 .06
Tb.Sp SD (mm) 0.419 ± 0.069 0.257 ± 0.012 .02
Total vBMD= total volumetric bone mineral density; Ct.vBMD= cortical volumetric bone mineral density;
Ct.Th= cortical thickness; Tb.vBMD= trabecular volumetric bone mineral density; Tb.N= trabecular
number; Tb.Th= trabecular thickness; Tb.Sp= trabecular separation; Tb.Sp.SD= trabecular distribution
57
Table 3: ITS and mechanical parameters in PHPT patients and controls:
ITS and mechanical
parameters PHPT (n=51) Control (n=120) p-value
Rad
ius
pBV/TV (%) 4.8 ± 0.4 6.9 ± 0.3 .0003
rBV/TV (%) 14.0 ± 0.6 16.1 ± 0.3 .0005
P-R ratio 0.334 ± 0.021 0.429 ± 0.019 .0037
aBV/TV (%) 6.1 ± 0.4 8.1 ± 0.2 <.0001
pTb.N (1/mm) 1.158 ± 0.030 1.296 ± 0.020 .0002
rTb.N (1/mm) 1.720 ± 0.029 1.811 ± 0.014 .0061
pTb.Th (mm) 0.204 ± 0.002 0.206 ± 0.000 .3466
rTb.Th (mm) 0.212 ± 0.000 0.214 ± 0.000 .0192
pTb.S (mm2) 0.135 ± 0.002 0.142 ± 0.003 .0441
rTb.ℓ (mm2) 0.710 ± 0.006 0.695 ± 0.008 .1717
R-R Junc.D (1/mm3) 2.451 ± 0.124 2.831 ± 0.066 .0042
P-R Junc.D (1/mm3) 2.207 ± 0.169 2.964 ± 0.109 .0003
P-P Junc.D (1/mm3) 0.966 ± 0.081 1.378 ± 0.057 .0001
Trab Stiffness (N/mm) 5,585± 943 10,359 ± 734 .0003
Stiffness (N/mm) 54,175 ± 2,845 69,567 ± 1,686 <.0001
Ctload distal (%) 50.0 ± 1.5 41.8 ± 0.9 <.0001
Ctload proximal (%) 95.3 ± 0.7 90.7 ± 0.6 <.0001
Tibi
a
pBV/TV (%) 9.1 ± 0.5 11.4 ± 0.4 .0006
rBV/TV (%) 14.3 ± 0.6 14.4 ± 0.3 .8894
P-R ratio 0.690 ± 0.046 0.852 ± 0.040 .0086
aBV/TV (%) 9.5 ± 0.3 11.3 ± 0.3 .0001
pTb.N (1/mm) 1.396 ± 0.022 1.475 ± 0.013 .0017
rTb.N (1/mm) 1.762 ± 0.031 1.746 ± 0.016 .6189
pTb.Th (mm) 0.216 ± 0.002 0.219 ± 0.001 .06
rTb.Th (mm) 0.213 ± 0.001 0.218 ± 0.000 .003
pTb.S (mm2) 0.149 ± 0.003 0.157 ± 0.003 .0384
rTb.ℓ (mm2) 0.669 ± 0.004 0.668 ± 0.006 .8882
R-R Junc.D (1/mm3) 2.549 ± 0.151 2.388 ± 0.073 .338
P-R Junc.D (1/mm3) 3.132 ± .0147 3.446 ± 0.077 .0427
P-P Junc.D (1/mm3) 1.619 ± 0.072 1.894 ± 0.045 .0014
Trab Stiffness (N/mm) 65,372 ± 4,248 80,078 ± 2,896 .0067
Stiffness (N/mm) 184,204 ± 6,187 205,746 ± 4,061 .005
Ctload distal (%) 30.2 ± 1.2 27.5 ± 0.8 .0649
Ctload proximal (%) 72.4 ± 0.01.6 70.1 ± 0.8 .1058
pBV/TV= plate bone volume fraction; rBV/TV= rod bone volume fraction; P-R ratio= plate-to-rod ratio;
aBV/TV= axial bone volume fraction; pTb.N= plate number density; rTb.N= rod number density;
pTb.Th= plate thickness; rTb.Th= rod thickness; pTb.S= plate surface area; rTb.ℓ= rod length; R-R
Junc.D= rod–rod junction density; P-R Junc.D= plate-rod junction density; P-P Junc.D= plate–plate
junction density, Trab. Stiffness= trabecular stiffness; Stiffness= whole bone stiffness; Ctload distal=
cortical load at distal surface; and Ctload proximal= cortical load at proximal surface
58
Table 4: Correlations (r values) between BMI and HRpQCT parameters at the radius and
at the tibia in subjects with PHPT and controls:
HRpQCT parameters
BMI (kg/m2)
Radial Comparisons Tibial Comparisons
PHPT Control PHPT Control
Total Area (cm2) 0.031 0.053 0.205 0.079
Total vBMD (mgHA/cm3) 0.249 0.299** 0.307* 0.340***
Ct.vBMD (mgHA/cm3) 0.023 0.148 -0.039 0.211*
Ct.Th (mm) 0.210 0.289** 0.158 0.341***
Tb.vBMD (mgHA/cm3) 0.312* 0.312** 0.396** 0.294**
Tb.N (1/mm) 0.287* 0.309** 0.533*** 0.226*
Tb.Th (mm) 0.109 0.164 -0.156 0.189
Tb.Sp (mm) -0.299* -0.324** -0.532*** -0.258*
Tb.Sp SD (mm) -0.295* -0.328** -0.487*** -0.165
*p<.05 ; **p<.01 ; ***p< .001
59
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66
3.2- Artigo 2:
Trabecular Bone Score – TBS – a novel method to evaluate bone microarchitecture in
patients with Primary Hyperparathyroidism
Artigo submetido ao “The Journal of Clinical Endocrinology & Metabolism”.
67
Trabecular Bone Score – TBS – a novel method to evaluate bone
microarchitecture in patients with Primary Hyperparathyroidism
Barbara C Silva1,2, Stephanie Boutroy1, Chiyuan Zhang1, Donald J McMahon1, Bin
Zhou3, Ji Wang3, Julia Udesky1, Serge Cremers1, Marta S. Sarquis2, X Edward Guo3,
Didier Hans4, John P Bilezikian1#
1- Metabolic Bone Diseases Unit, Division of Endocrinology, Department of Medicine, College of
Physicians and Surgeons, Columbia University, New York, NY, USA
2- College of Medicine of Federal University of Minas Gerais, Belo Horizonte, Brazil
3- Bone Bioengineering Laboratory, Department of Biomedical Engineering, Columbia University,
New York, NY, USA
4- Center of Bone diseases, Lausanne University Hospital, Lausanne, Switzerland
# Correspondence to:
John P. Bilezikian. M.D.
College of Physicians and Surgeons
630 W, 168th Street, New York, NY 10032, USA
Phone: 212.305.6257
Fax: 212.305.6486
e-mail: [email protected]
68
Abstract:
Introduction: Typically, in the milder form of primary hyperparathyroidism (PHPT),
aBMD by DXA is reduced at the predominantly cortical 1/3 radius, while cancellous
bone, represented by aBMD at the lumbar spine, is generally preserved. Recent studies
utilizing High Resolution peripheral Quantitative Computed Tomography (HRpQCT) has
shown, however, that both cortical and trabecular bone compartments are compromised in
PHPT, which agrees with epidemiology evidence for increased overall fracture risk in this
disease. Since DXA cannot direct measure trabecular bone, and HRpQCT is not widely
available, we used trabecular bone score (TBS), a novel gray-level textural analysis that
can be applied to spine DXA images, to estimate trabecular microarchitecture.
Aims: To assess TBS from spine DXA images in postmenopausal women with PHPT in
relation to HRpQCT indices and bone stiffness.
Patients and Methods: 22 women (67 ± 2 yr.) with PHPT were studied. aBMD was
assessed by DXA (QDR 4500A, Hologic), and site-matched spine TBS indices were
derived from DXA images using TBS iNsight software (v1.9, Medimaps SA). By
HRpQCT, distal radius and tibia analyses were performed, and bone stiffness at these
sites was assessed by finite element analysis (FEA).
Results: TBS in PHPT is abnormal representing a partially degraded microstructure. The
mean value was 1.24 ± 0.02 (definition of normal here). TBS was significantly correlated
with all HRpQCT and mechanical measurements except for Tb.Th, and trabecular
stiffness at the radius. At the tibia, significant correlations were observed between TBS
and volumetric densities, Ct.Th, BV/TV and whole bone stiffness. All indices of
trabecular microarchitecture, except Tb.Th, became significant after adjusting for body
weight.
Conclusion: TBS showed significant correlations with biomechanical and
microstructural indices by HRpQCT. TBS shows promise as a readily available
measurement tool in the assessment of trabecular microstructure in PHPT.
Key words: Primary hyperparathyroidism, trabecular bone score, high-resolution
peripheral quantitative computed tomography, finite element analysis, fracture risk.
69
Introduction
Primary hyperparathyroidism (PHPT) is a common endocrine disorder characterized by
hypercalcemia and elevated or inappropriately normal levels of parathyroid hormone
(PTH). With the advent of the multichannel autoanalyzer in the early 1970’s, the clinical
presentation of PHPT changed from symptomatic (1) to asymptomatic (2-4). While overt
skeletal disease, formerly a common finding, is rarely seen now, bone mineral
densitometry (aBMD) routinely detects evidence for skeletal involvement. The distal 1/3
radius, a site of cortical bone, is typically more involved than the lumbar spine, a site
comprised predominantly of trabecular bone (5). These findings, however, are not
consistent with recent observations utilizing technologies that have greater resolving
power than DXA, such as High Resolution peripheral Quantitative Computed
Tomography (HRpQCT) in which trabecular microarchitectural deficits are seen (6, 7).
By HRpQCT, both trabecular and cortical compartments are abnormal at the radius and
tibia in postmenopausal women with PHPT. These deficits are associated with reduced
whole bone and trabecular stiffness by FEA (7). Hansen et al. (6) have also observed
similar structural deficits at the distal radius in PHPT. These more recent findings by
HRpQCT and FEA are consistent with epidemiological evidence of increased fracture
risk at both vertebral and non-vertebral sites in PHPT (8-11). While HRpQCT has added
a dimension of insight not previous appreciated with regard to trabecular bone in PHPT,
HRpQCT is not widely available and, considering the cost of the instrumentation, is not
likely to be.
Trabecular bone score (TBS) is a novel gray-level textural analysis that can be applied to
DXA images to estimate trabecular microarchitecture (12). Using experimental
variograms of 2D projection images, TBS differentiates between 3D bone structures that
exhibit the same aBMD, but different trabecular microarchitecture (13). TBS analysis is
readily available from the lumbar spine DXA image without the need for further imaging
or expensive instrumentation. Studies in cadaveric bones have shown significant
correlations between TBS and 3D trabecular microarchitecture measurements by micro-
computed tomography (µCT) (12, 13). In clinical studies, TBS enhanced DXA’s ability
to predict fracture risk (14-19). Moreover, in a recent study involving over 29,000
postmenopausal women, TBS predicted osteoporotic fractures, independent of aBMD
(19). Finally, Boutroy et al. (20) showed that TBS predicts osteoporotic fracture as well
70
as lumbar spine aBMD, and that TBS helped to define a subset of non-osteoporotic
women at high risk for fracture.
The ability of TBS to estimate trabecular microarchitecture and predict fracture risk,
along with its direct utilization from DXA images led us to investigate its potential utility
in evaluating the trabecular skeleton in PHPT. To this end, we assessed TBS from spine
DXA images in postmenopausal women with PHPT, and correlated it, for the first time,
with HRpQCT measurements of volumetric bone density, skeletal microarchitecture, and
bone stiffness. Our results indicate that TBS has the potential to provide additional data
on trabecular bone quality in PHPT and that it can be readily applied without the need for
expensive equipment.
71
Patients and Methods
Study Subjects:
22 postmenopausal women were recruited from Columbia University Medical Center
(CUMC). Subjects were eligible for inclusion if they had well-characterized PHPT
(elevated serum calcium and elevated or inappropriately normal PTH levels). Exclusion
criteria included use of bisphosphonates or glucocorticoids within the past 2 years, history
of Cushing’s syndrome, uncontrolled thyroid disease, malabsorption syndrome,
significant liver disease, creatinine clearance < 30 mL/min, and any chronic disorders of
mineral metabolism such as Paget’s disease or osteogenesis imperfecta. Women were
considered postmenopausal if they had not had a menstrual period for over 1 year.
The study was approved by the Institutional Review Board of Columbia University
Medical Center, and all subjects gave written informed consent.
Dual-energy X-ray absorptiometry (DXA):
aBMD by DXA was measured at the lumbar spine (L1–L4), total hip, femoral neck, and
nondominant forearm [ultradistal (UD radius) and one-third radius (1/3 radius)] using
Discovery A (Hologic Inc., Bedford, MA, USA) at CUMC. Bone density was expressed
in T-score for comparisons of subjects with young-normal population.
Trabecular Bone Score (TBS):
Site-matched spine TBS parameters were extracted from the DXA image using TBS
iNsight software (v1.9, Medimaps SA, France). TBS measurements were performed in
the Bone Disease Unit at the University of Lausanne, Lausanne, Switzerland, using de-
identified spine DXA files from scans obtained at CUMC. TBS was evaluated, by
determining the variogram of the trabecular bone projected image, calculated as the sum
of the squared gray-level differences between pixels at a specific distance. TBS was then
calculated as the slope of the log-log transform of this variogram (13). TBS was assessed
in the same regions of measurement as those used for the lumbar spine BMD. The mean
value of the individual measurements for L1 to L4 represents the lumbar spine TBS.
To ensure comparability with previous TBS studies, calibration on the DXA machine at
CUMC was performed using a TBS-specific phantom (MedImaps). From previous
reports, based upon over 29 thousands female subjects, TBS≤1.2 is described as degraded
72
microarchitecture, TBS between 1.20 and 1.35 is partially degraded microarchitecture,
and TBS≥1.35 is considered normal (18-23)
High Resolution peripheral Quantitative Computed Tomography (HRpQCT):
Volumetric bone mineral density (vBMD) and microarchitecture were measured at the
nondominant distal radius and tibia using the HRpQCT system (Xtreme CT; Scanco
Medical AG, Brüttisellen, Switzerland) at CUMC, as previously described (24)
Image analysis has been validated and detailed elsewhere (24-27). The following indices
were evaluated at the distal radius and tibia: total area; total, cortical and trabecular
volumetric bone densities (Total vBMD, Ct.vBDM and Tb.vBMD, respectively); cortical
thickness (Ct.Th); trabecular bone volume (BV/TV); trabecular number (Tb.N);
trabecular thickness (Tb.Th); trabecular separation (Tb.Sp); and standard deviation of
trabecular separation (Tb.Sp. SD), a parameter reflecting the heterogeneity of the
trabecular network.
Finite Element Analysis (FEA) of HRpQCT images:
FEA was performed to estimate whole bone and trabecular stiffness by converting whole
bone and trabecular HRpQCT images into finite-element models. For each FE model, a
uniaxial compression test was performed with displacement equivalent to 1% apparent
strain to calculate stiffness. Bone tissue was assumed to have an isotropic linear material
property with Young’s modulus 15 GPa and Poisson’s ratio 0.3. Whole bone stiffness
was defined as reaction force divided by the applied displacement. It characterizes the
mechanical competence of both cortical and trabecular compartments and it is closely
related to whole bone strength (28). Similarly, trabecular bone stiffness characterizes the
mechanical competence of the trabecular bone compartment.
Biochemical analysis
Serum total calcium and albumin were measured using standard methods (Quest
Diagnostics, Madison, NJ, USA) and calcium values were corrected for low albumin
(albumin < 4 g/dL). Intact PTH was measured by immunoradiometric assay
(Scantibodies, Santee, CA, USA) in the Bone Marker Laboratory at CUMC. The normal
range was 14 to 66 pg/mL, and the precision inter- and intra-assay coefficients were < 7%
and 5%, respectively.
73
Statistical Analysis:
Descriptive statistics are expressed as mean ± SEM. Correlation of TBS with HRpQCT
indices, mechanical parameters and DXA measurements was assessed by the Pearson
correlation test. Since Tb.Sp and Tb.Sp SD did not follow a normal distribution, they
were log-transformed and then correlated using Pearson Correlation. Correlations
adjusted of weight were performed by partialing out weight. Linear regression analyses
were applied to estimate the variability in HRpQCT and mechanical parameters when
TBS, aBMD at the lumbar spine or the combination of both were used as the explanatory
variables. All statistical tests were performed at the two-sided 0.05-level of significance.
Statistical analysis was performed using SAS, version 9.2 (SAS Institute, Inc., Cary, NC,
USA).
74
Results
Baseline characteristics of 22 postmenopausal women with PHPT are described in Table
1. The majority of PHPT patients (77%) were asymptomatic. Only 1 subject had a history
of nephrolithiasis, while 4 had a history of fragility fracture.
TBS and aBMD by DXA:
Mean TBS, aBMD and T-scores by DXA are reported in Table 1. Although the
prevalence of osteoporosis at any site was 50%, L1-L4 T-score by DXA was well above
the WHO osteoporosis threshold (T-score ≤2.5) in the vast majority of subjects. Only 3
(14%) patients were classified as osteoporotic, 7 (32%) as osteopenic, whereas the
remaining 12 (53%) subjects presented with normal L1-L4 T-scores by DXA.
In contrast, TBS at the lumbar spine showed degraded microarchitecture (TBS≤1.20) in 8
(36%) patients, partially degraded (TBS>1.20 and <1.35) in an additional 8 (36%), and
normal values (TBS≥1.35) in only 6 (27%) subjects (Figure 1A and 1B). The mean TBS
of the whole group was 1.24, representing a partially degraded microarchitecture.
Relationship between TBS and aBMD by DXA:
Correlations between TBS and aBMD at the lumbar spine (r=0.367), total hip (r=0.269),
and femoral neck (r=0.350) were not significant, whereas significant correlations were
found between TBS and aBMD at the 1/3 radius (r=0.427; p=0.047), and UD radius
(r=0.450; p=0.036).
Relationship between TBS, HRpQCT and mechanical parameters:
As shown in Table 2, at the radius, TBS was significantly correlated with all HRpQCT
and biomechanical measurements except total area, Tb.Th, and trabecular stiffness.
Significant correlations remained after adjusting for body weight (Table 2 and Figure 2).
At the tibia, significant correlations were observed between TBS and volumetric
densities, Ct.Th, BV/TV and whole bone stiffness. All indices of trabecular
microarchitecture, except Tb.Th, became significant after adjusting for body weight
(Table 2 and Figure 2).
Using linear regression analysis, TBS or L1-L4 aBMD alone explained 20 to 50% of
variances in HRpQCT measurements of volumetric densities, Ct.Th, BV/TV and whole
bone stiffness at the radius and tibia. TBS and aBMD together better predict the
75
variability in these HRpQCT indices and whole bone stiffness than either one alone
(Table 3).
At the radius, TBS explained 25% and 20% of the variance in Tb.N and Tb.Sp,
respectively, with a slight increase in the degree of variance explained by the combination
of TBS with L1-L4 aBMD (Table 3). At the tibia, TBS was a poor predictor of the
variances in HRpQCT measurements of trabecular microarchitecture.
76
Discussion
The results of this study show, for the first time, significant correlations between TBS and
HRpQCT measurements of volumetric densities, skeletal microarchitecture and bone
stiffness at the radius and tibia, in a group of postmenopausal women with PHPT.
Previous HRpQCT studies have shown that not only cortical, but also trabecular bone, is
compromised in PHPT, even in the mild form of this disease (6, 7). This technology,
however, is not widely accessible, and a clinical tool to assess trabecular
microarchitecture could be helpful in the evaluation of this disease. TBS, an indirect
measurement of trabecular microarchitecture, is now an FDA-approved application to
DXA and readily available. Significant correlations between TBS and HRpQCT indices
demonstrated here indicate that it may serve as a valuable additional index in the
assessment of skeletal microstructure in PHPT.
Significant correlations between TBS and 3D direct measurements of trabecular
microstructure were previously observed in human cadaver bone specimens (vertebrae,
femur and radius) (12, 13). The TBS pivotal study showed significant relationships
between TBS evaluated from 2D projection images directly derived from 3D µCT
reconstruction and direct 3D measurements of trabecular microarchitecture by µCT (12).
Following this observation, TBS was derived from DXA images of lumbar vertebrae, and
significant correlations between trabecular indices by µCT and TBS were confirmed (13).
In agreement with these data, we observed a positive correlation of TBS with BV/TV and
Tb.N, and a negative correlation with Tb.Sp and Tb.Sp. SD at the radius. Similar results
were shown at the tibia after adjusting for body weight. TBS did not show a significant
relationship with Tb.Th at the radius or tibia, even after adjusting for weight. In fact,
unexpected inverse correlation between TBS and Tb.Th was previously found in an ex
vivo study (13), and the reason for this observation is not clear.
Unadjusted correlations between TBS at the lumbar spine and trabecular indices of
microstructure at the tibia were not significant. Although lumbar spine and tibia are both
load-bearing sites, they are subjected to different loading forces, which might explain this
observation. In fact, after adjusting for body weight, a surrogate for mechanical loading,
correlations of TBS with Tb.N, Tb.Sp and Tb.Sp SD became significant at the tibia.
Differences in the quality of trabecular bone can also be appreciated when HRpQCT
findings are compared with histomorphometric and µCT analyses of iliac crest bone
77
biopsies in PHPT. While both cortical and trabecular bone are affected at peripheral sites
by HRpQCT, histomorphometry and µCT studies of iliac crest biopsies show that
trabecular bone volume, number, separation and connectivity are either preserved or
increased in patients with PHPT (29-33). Cohen et al. (34) have also found modest or no
correlations between microarchitecture parameters as assessed by HRpQCT of radius and
tibia and histomorphometry and µCT of iliac crest biopsies. Since previous studies have
shown strong correlations between microarchitecture assessed by HRpQCT and
histomorphometry or µCT at the same bony regions (26, 35), site-to-site differences are
likely to contribute to the weak correlations observed by Cohen et al. (34). The discrepant
observations by histomorphometric analysis of bone biopsies vis a vis fracture incidence
in this disease suggest that HRpQCT and now TBS might be more clinically pertinent to
fracture risk in PHPT.
Despite the fact that TBS estimates trabecular microarchitecture, our results also revealed
positive correlations of TBS with Ct.vBMD and Ct.Th at the radius and tibia. This is not
surprising, since cortical and trabecular compartments are both affected in PHPT, leading
to strong correlations between measurements of trabecular and cortical microarchitecture
and density, even among HRpQCT indices (e.g. correlation between Tb.N and Ct.Th at
the radius: r=0.667; p=0.001).
The results of this study also showed positive correlations between TBS and whole bone
stiffness at the radius (r=0.442; p=0.04) and tibia (r=0.516; p=0.02) as measured by FEA
of HRpQCT images. An ex vivo study on 16 human vertebrae confirmed the positive
relationship between TBS and mechanically measured bone strength (36). Reduced bone
stiffness assessed by FEA of HRpQCT images, as well as low TBS, have been associated
with fragility fractures in postmenopausal women (14-16, 18-20, 37-39). Even though
these studies did not involve patients with PHPT, our findings suggest that low TBS may
be related with decreased bone stiffness, and consequently, fracture risk, also in PHPT.
Although we observed significant correlations between TBS and HRpQCT parameters of
volumetric densities, skeletal microarchitecture and bone stiffness, it is important to note
that, by linear regression analysis, variations in HRpQCT indices of trabecular
microarchitecture and stiffness were better predicted by L1-L4 aBMD. The combination
of TBS and L1-L4 aBMD was slightly better in predicting the variance of those HRpQCT
78
indices than either one alone. Moreover, TBS was a poor predictor of variances in
HRpQCT measurements of trabecular microarchitecture at the tibia. Since these
relationships are comparing TBS, an indirect measurement of trabecular
microarchitecture at the lumbar spine, with measurements of cancellous microstructure at
the radius and tibia (HRpQCT), it is possible that site-to-site differences in the trabecular
compartment are, again, contributing to these observations. In fact, when TBS, aBMD
and measurements of trabecular microstructure by µCT were assessed at the same bony
region, correlations of aBMD and TBS with BV/TV, Tb.N, Tb.Sp and connectivity
density were similar (13).
As reported previously (22, 40), we observed modest or no correlation between TBS and
aBMD at all sites. Weak relationships of TBS with aBMD at the lumbar spine (r=0.33),
femoral neck (r=0.27) and total hip (r=0.26) were also reported in The Manitoba Study
(19). Similarly, recent studies evaluating the effect of anti-resorptives, and more
specifically, zoledronic acid therapy on TBS confirmed weak or no correlation between
treatment-changes in TBS and aBMD (40, 41). The poor correlation between TBS and
aBMD at the lumbar spine, despite the fact that both evaluate the same region of bone,
implies that these measurements are, at least, partial independent of each other. In
contrast, Boutroy et al. (20) found significant correlations between TBS and L1-L4
aBMD (r=0.58; p<0.001) in 560 women from the OFELY cohort. There may be a
tendency for higher correlations between these two indices when Hologic scanners are
used (20, 42) as opposed to GE-Lunar DXA devices (19, 41). This observation, however,
is not universal (18, 43), and the reason for these paradoxical findings is still unclear.
A TBS threshold of 1.200 has been used in numerous studies to identify patients at high
risk of fracture. Results from these studies, which involved from 500 to 1,200
postmenopausal women, have shown that a significant greater number of subjects at high
risk of fragility fracture are identified when a combination of either aBMD T-score ≤2.5
or TBS <1.200 are considered, as opposed to aBMD T-score ≤2.5 alone (18, 22, 23).
Similarly, in the study of Boutroy et al. (26), non-osteoporotic women whose TBS values
were below 1.209 (the first TBS quartile threshold) had a significant higher incidence of
fragility fracture. Using cut off points previously reported as having the best sensitivity
and specificity in regards to fracture, we showed that 36% of PHPT patients had a
degraded microarchitecture (TBS≤1.20), an additional 36% a partially degraded
79
microarchitecture (TBS>1.20 and <1.35) and 27% of them presented normal TBS values
(TBS≥1.35). Accordingly, while 72% of PHPT patients showed degraded or partially
degraded microarchitecture by TBS, only 46% of them were classified as osteopenic or
osteoporotic by lumbar spine T-score. Similarly, patients with PHPT were found to have
lower TBS values than healthy controls, despite similar lumbar spine aBMDs by DXA
(42). Therefore, TBS may help to identify abnormalities in trabecular bone in PHPT even
in patients with apparent preserved lumbar spine aBMD by DXA.
This study has some limitations. We studied a fairly small number of subjects, so that we
could not evaluate the association between TBS and fracture risk in PHPT. Moreover, it
remains to be seen whether these findings would be appreciated when a larger number of
patients is studied. We did not include a healthy control group, since our main aim was to
correlate TBS with HRpQCT-derived measurements of microarchitecture and
biomechanical competence in PHPT. However, it would be helpful to compare TBS
between PHPT and control subjects, as well as to verify if the significant correlations
reported here are also present in healthy individuals. Only postmenopausal women were
studied so that it is not known whether the results are applicable to men or premenopausal
women with PHPT.
Despite these limitations, our study has important strengths. This is the first clinical study
to report significant correlations between TBS and direct measurements of trabecular
microstructure by HRpQCT. The positive relationship between TBS and bone stiffness
assessed by FEA of HRpQCT images suggest that, in PHPT, low TBS may also indicate
increased fracture risk. Moreover, our results demonstrate that TBS has the potential to
identify PHPT subjects with abnormalities in trabecular bone not captured by lumbar
spine aBMD. TBS has the major clinical advantage of being readily available from
images of DXA, a test routinely performed in PHPT. With significant correlations
between TBS and volumetric and microstructural indices, as well as biomechanical
measurements by HRpQCT, a method that has greater resolving power but is not widely
accessible, TBS could become a helpful clinical tool in the assessment of skeletal
involvement in PHPT.
80
Disclosures:
Didier Hans is a co-owner of the TBS patent. The other authors state that they have no
conflicts of interest.
Acknowledgments:
Supported in part by the following NIH grants: DK32333, and the Brazilian National
Council of Technological and Scientific Development – CNPq (BC Silva).
81
Figures:
Figure 1: Comparison of aBMD by DXA and TBS. Prevalence of subjects with: (A)
osteoporosis, osteopenia or normal aBMD at the lumbar spine by DXA; and (B) degraded
microarchitecture (TBS<1.2), partially degraded microarchitecture (TBS>1.2 and <1.35),
and normal TBS at the lumbar spine (TBS>1.35).
DXA= dual-energy X-ray absorptiometry; aBMD= areal bone mineral density; and TBS=
trabecular bone score.
82
Figure 2: Correlations adjusted for body weight between TBS and trabecular number
(A), trabecular separation (B), and stiffness (C) at the radius; and trabecular number (D),
trabecular separation (E), and stiffness (F) at the tibia.
TBS= trabecular bone score; Tb.N= trabecular number; Tb.Sp= trabecular separation;
Stiffness= whole bone stiffness
83
Table 1: Baseline characteristics of 22 subjects with PHPT:
Characteristics PHPT (n=22)
Age (years) 67± 2
Weight (kg) 71 ± 4
Height (cm) 161.5 ± 1.9
BMI (kg/cm2) 27.2 ± 1.5
Years since menopause 15 ± 2
Years since diagnosis 6 ± 1
Serum total calcium (mg/dL) 10.4 ± 0.1
PTH (pg/mL) 72 ± 9
TBS 1.24 ± 0.02
L1-L4 BMD (g/cm2) 0.940 ± 0.039
T-score -1.0 ± 0.4
Total hip BMD (g/cm2) 0.808 ± 0.035
T-score -1.1 ± 0.3
Femoral neck BMD (g/cm2) 0.693 ± 0.030
T-score -1.4 ± 0.3
1/3 radius BMD (g/cm2) 0.616 ± 0.022
T-score -1.3 ± 0.4
UD radius BMD (g/cm2) 0.361 ± 0.018
T-score -1.4 ± 0.3
84
Table 2: Correlation between TBS and HRpQCT/mechanical parameters at the radius and
tibia in subjects with PHPT:
HRpQCT and mechanical parameters TBS
r-value r-value adjusted for weight
Rad
ius
Total area -0.153 -0.063
Total vBMD 0.489* 0.536*
Ct.vBMD 0.507* 0.512*
Ct.Th 0.453* 0.480*
Tb.vBMD 0.476* 0.562*
BV/TV 0.473* 0.559*
Tb.N 0.505* 0.620*
Tb.Th 0.317 0.337
Tb.Sp (LOG) -0.492* -0.580*
Tb.Sp SD (LOG) -0.441* -0.533*
Trab. Stiffness 0.332 0.326
Stiffness 0.442* 0.530*
Tibi
a
Total area -0.373 -0.259
Total vBMD 0.619* 0.668*
Ct.vBMD 0.471* 0.465*
Ct.Th 0.515* 0.545*
Tb.vBMD 0.528* 0.606*
BV/TV 0.530* 0.608*
Tb.N 0.297 0.573*
Tb.Th 0.056 -0.112
Tb.Sp (LOG) -0.365 -0.524*
Tb.Sp SD (LOG) -0.390 -0.483*
Trab. Stiffness 0.262 0.403
Stiffness 0.516* 0.609*
*p<0.05
TBS= trabecular bone score; Total vBMD= total volumetric bone mineral density; Ct.vBMD= cortical
volumetric bone mineral density; Ct.Th= cortical thickness; Tb.vBMD= trabecular volumetric bone mineral
density; BV/TV= trabecular bone volume; Tb.N= trabecular number; Tb.Th= trabecular thickness; Tb.Sp=
trabecular separation; Tb.Sp.SD= trabecular distribution; Trab. Stiffness= trabecular stiffness; Stiffness=
whole bone stiffness
85
Table 3: Univariate or multivariate linear regression analysis to predict the variability in
HRpQCT indices and mechanical parameters:
HRpQCT and
mechanical parameters TBS (R2) L1-L4 BMD (R2)
TBS + L1-L4 BMD
(R2)
Rad
ius
Total Area 0.023 0.004 0.039
Total vBMD
(mgHA/cm3)
0.239* 0.330* 0.420*
Ct. vBMD 0.257* 0.209* 0.342*
Ct.Th 0.205* 0.233* 0.321*
Tb. vBMD 0.227* 0.479* 0.536*
BV/TV 0.224* 0.479* 0.534*
Tb.N 0.255* 0.460* 0.536*
Tb.Th 0.100 0.269* 0.287*
Tb.Sp 0.208* 0.345* 0.411*
Tb.Sp SD 0.161 0.315* 0.359*
Trab Stiffness 0.110 0.365* 0.379*
Stiffness 0.195* 0.522* 0.558*
Tibi
a
Total Area 0.139 0.004 0.187
Total vBMD
(mgHA/cm3)
0.383* 0.369* 0.550*
Ct. vBMD 0.222* 0.209* 0.315*
Ct.Th 0.265* 0.276* 0.396*
Tb. vBMD 0.278* 0.345* 0.458*
BV/TV 0.280* 0.345* 0.459*
Tb.N 0.088 0.642* 0.642*
Tb.Th 0.003 0.184* 0.237
Tb.Sp 0.127 0.343* 0.366*
Tb.Sp SD 0.123 0.277* 0.306*
Trab Stiffness 0.069 0.123 0.141
Stiffness 0.266* 0.444* 0.518*
*p<.05
TBS= trabecular bone score; Total vBMD= total volumetric bone mineral density; Ct.vBMD= cortical
volumetric bone mineral density; Ct.Th= cortical thickness; Tb.vBMD= trabecular volumetric bone mineral
density; BV/TV= trabecular bone volume; Tb.N= trabecular number; Tb.Th= trabecular thickness; Tb.Sp=
trabecular separation; Tb.Sp.SD= trabecular distribution; Trab. Stiffness= trabecular stiffness; Stiffness=
whole bone stiffness
86
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92
4- CONSIDERAÇÕES FINAIS:
Resultados desse estudo reafirmam a necessidade de se reconsiderar o conceito de que,
nas formas assintomáticas de PHPT, apenas o osso cortical é comprometido. Além disso,
indicam que outras técnicas de avaliação óssea, combinadas à avaliação por DXA, podem
fornecer informações adicionais sobre qualidade óssea nessa entidade. Uma vez que o
achado de osteoporose em exames de densitometria óssea é uma das indicações para o
tratamento cirúrgico das formas assintomáticas de PHPT (BILEZIKIAN et al., 2009), é
importante que a integridade óssea seja avaliada com precisão, evitando-se o
subtratamento da doença.
Avaliação óssea por HRpQCT de 51 mulheres na pós menopausa com PHPT evidenciou
que, mesmo na forma assintomática da doença, os compartimentos cortical e trabecular
estão sujeitos a ações negativas do excesso crônico de PTH. Verificou-se redução da
vBMD em ambos compartimentos esqueléticos do rádio distal e da tíbia. Esses achados
são compatíveis com estudos prévios por pQCT (CHEN et al., 2003; CHAROPOULOS
et al., 2006), mas tal técnica não permite avaliação da microestrutura óssea. Resultados
do único estudo de HRpQCT em pacientes com PHPT (HANSEN et al., 2010)
confirmam nossos achados de redução generalizada da vBMD e deterioração da
microarquitetura cortical e trabecular, mas, naquele estudo, as diferenças foram
significativas apenas no rádio, talvez pelo número menor de pacientes avaliados (26,
sendo 23 mulheres na pós menopausa).
Este projeto inaugura o uso de ITS para análise de imagens de HRpQCT no PHPT.
Análise por ITS mostrou que, no PHPT, há redução maior de trabéculas em placa do que
em haste, resultando em diminuição significativa da razão P-R. Uma vez que trabéculas
em placa são as principais responsáveis pela resistência óssea (LIU et al., 2008), essa
alteração microestrutural do compartimento trabecular resultaria em aumento da
fragilidade óssea nessa doença. Além disso, ITS revelou redução do aBV/TV, variável
fortemente correlacionada com medidas de competência mecânica óssea (LIU et al.,
2008). Associadas a essas alterações estruturais, redução da rigidez óssea total e
trabecular, bem como aumento da carga suportada pelo compartimento cortical,
93
estimados por FEA, confirmam os efeitos negativos do PTH sobre a qualidade óssea
cortical e trabecular em pacientes com PHPT.
Confirmando achados de estudos anteriores, resultados deste trabalho demonstraram que
aBMDs da coluna lombar foram semelhantes entre casos e controles. A inabilidade da
densitometria óssea em detectar perda esquelética trabecular no PHPT poderia ser
explicada por diferenças na geometria óssea. Nossos estudos de HRpQCT revelaram que
pacientes com PHPT têm aumento da área óssea total. Uma vez que a medida da aBMD é
influenciada pelo tamanho ósseo (CARTER et al., 1992), o aumento da área óssea
poderia superestimar a medida da aBMD nesses pacientes. Além disso, é possível que
sítios ósseos diferentes respondam de maneira diversa ao excesso crônico de PTH. De
fato, ausência de anormalidades no compartimento trabecular foi também observada por
histomorfometria de biópsias ósseas de crista ilíaca, em estudos anteriores de pacientes
com PHPT (PARISIEN et al., 1990; CHRISTIANSEN et al., 1992; PARISIEN et al.,
1992; PARISIEN et al., 1995). Dado que medidas de microarquitetura trabecular por
HRpQCT têm forte correlação com resultados de histomorfometria quando o mesmo sítio
ósseo é avaliado (BOUTROY et al., 2011), é possível que o fato de se ter avaliado sítios
ósseos distintos explique os achados divergentes entre estudos de HRpQCT do rádio e
tíbia e estudos histomorfométricos da crista ilíaca. Mesmo entre os dois sítios periféricos
aqui avaliados, rádio e tíbia, há diferenças consideráveis. As ações deletérias do PTH
sobre o osso trabecular foram menos evidentes na tíbia, possivelmente por tratar-se,
diferente do rádio, de osso sujeito a sobrecarga mecânica.
Este trabalho não avaliou o risco de fratura em pacientes com PHPT. No entanto, estudos
anteriores confirmam que redução da vBMD no rádio e tíbia por HRpQCT, bem como
anormalidades na microarquitetura trabecular e cortical, estão relacionadas a risco
aumentado de fratura osteoporótica vertebral e não vertebral em mulheres na pós
menopausa (SORNAY-RENDU et al., 2007; STEIN et al., 2010; STEIN et al., 2011;
STEIN et al., 2012). Da mesma forma, redução da rigidez óssea estimada por FEA, e
redução do volume de trabéculas em placa, menor fração de volume trabecular alinhado
no sentido axial e redução da conectividade entre placas, hastes e entre placas e hastes,
avaliados por ITS, distinguiram mulheres com fratura por fragilidade de controles
saudáveis (BOUTROY et al., 2008; STEIN et al., 2010; VILAYPHIOU et al., 2010;
STEIN et al., 2011; LIU et al., 2012). Dessa forma, as alterações estruturais e
94
biomecânicas evidenciadas em mulheres com PHPT neste estudo, similares às descritas
em estudos que consideraram fratura como desfecho principal, são compatíveis com
aumento do risco de fratura nessa doença.
Apesar de ter fornecido informações importantes sobre qualidade óssea em pacientes com
PHPT e de ser um método não invasivo e de alta sensibilidade, a HRpQCT é um exame
de alto custo e indisponível na maior parte dos centros médicos. Por isso, avaliamos se o
TBS, novo método de análise de imagem, potencialmente disponível em qualquer centro
médico que realize exames de densitometria óssea, poderia fornecer informações
adicionais sobre a qualidade do esqueleto trabecular, constituindo uma alternativa para
avaliação de pacientes com PHPT na prática clínica.
TBS foi desenvolvido para estimar a microarquitetura trabecular, podendo ser empregado
a qualquer imagem de densitometria óssea de coluna lombar. Estudos clínicos
envolvendo grande número de mulheres na pós menopausa confirmaram sua habilidade
em predizer fratura por fragilidade (POTHUAUD et al., 2009; RABIER et al., 2010;
WINZENRIETH et al., 2010; HANS et al., 2011b; DEL RIO et al., 2012). Neste estudo,
estimamos, pela primeira vez, a correlação entre TBS, parâmetros de HRpQCT e índices
de rigidez óssea medidos por FEA em um subgrupo de 22 mulheres com PHPT.
TBS correlacionou-se com todos os índices determinados pela HRpQCT no rádio, exceto
Tb.Th e rigidez trabecular. Na tíbia, correlações foram observadas entre TBS e
densidades volumétricas, Ct.Th, BV/TV e rigidez de osso total. No entanto, correlações
entre TBS e Tb.N, Tb.Sp e Tb.Sp.SD na tíbia foram evidentes apenas após ajuste para
peso corporal. Da mesma forma, em modelos de análise de regressão linear, TBS foi
incapaz de prever variações nos índices de microestrutura trabecular da tíbia. Acredita-se
que essa falta de correlação entre TBS e estas medidas na tíbia seja explicada por
diferenças na microestrutura trabecular inerentes a sítios ósseos distintos. Uma vez que
coluna lombar e tíbia estão sujeitas a sobrecargas mecânicas diversas, sua estrutura
trabecular adapta-se de modo próprio. O fato da correlação ter-se tornado significativa
após ajuste para peso corporal, usado como substituto de sobrecarga mecânica, apoia essa
teoria. Além disso, observou-se correlação significativa entre TBS e medidas de
microestrutura trabecular por µCT quando ambos foram estimados no mesmo sítio ósseo
(HANS et al., 2011a). Por outro lado, a falta de correlação entre TBS e Tb.Th no rádio e
95
na tíbia, reflete, possivelmente, a falta de habilidade do TBS em estimar essa variável. De
fato, quando TBS foi correlacionado com medidas de microarquitetura trabecular por
µCT em estudo ex vivo, a correlação entre TBS e Tb.Th foi, inesperadamente, negativa
(HANS et al., 2011a). O motivo desse achado é desconhecido.
Apesar de não termos estudado risco de fratura, os achados de correlação positiva entre
TBS e rigidez de osso total estimada por FEA sugerem que, a exemplo de estudos prévios
em mulheres na pós menopausa, valores baixo de TBS podem estar relacionados a
redução da resistência óssea e, consequentemente, maior risco de fratura também em
pacientes com PHPT.
Confirmando estudos prévios (HANS et al., 2011b; LAMY et al., 2012; POPP et al.,
2012), não houve correlação significativa entre aBMD na coluna lombar e TBS,
indicando que as duas medidas, apesar de calculadas a partir da mesma região de
interesse, são, pelo menos, parcialmente independentes.
Baseado em estudos prévios, os seguintes pontos de corte foram sugeridos para
classificação de TBS em mulheres na pós menopausa: TBS≤1,20= microarquitetura
degradada; TBS entre 1,20 e 1,35= microarquitetura parcialmente degradada; TBS
≥1,35= microarquitetura normal. De acordo com essa classificação, TBS médio da nossa
população de estudo foi indicativo de microarquitetura trabecular parcialmente degradada
(TBS= 1,24). Enquanto 72% das pacientes com PHPT evidenciaram TBS compatível
com microarquitetura degradada ou parcialmente degradada, apenas 46% delas foram
classificadas como osteoporóticas ou osteopênicas pela avaliação do T-score da coluna
lombar. De maneira similar, estudo recente demonstrou que TBS foi significativamente
menor em grupo de pacientes com PHPT do em um grupo controle, apesar de valores
semelhantes de aBMD da coluna lombar entre os dois grupos (ROMAGNOLI et al.,
2012). Dessa forma, é possível que TBS ajude a identificar anormalidades no osso
trabecular em pacientes com PHPT com aparente preservação da aBMD em coluna
lombar por densitometria óssea.
Esses resultados demonstraram que TBS, além de poder ser calculado a partir de qualquer
imagem de densitometria óssea da coluna lombar, correlaciona-se significativamente com
96
índices de densidade volumétrica, microestrutura e rigidez de osso total estimados por
HRpQCT em pacientes com PHPT. Apesar do número pequeno de pacientes estudados, é
possível que, se avaliado em combinação com a medida de aBMD, TBS identifique maior
número de pacientes com deterioração óssea trabecular do que a avaliação da aBMD
isoladamente.
Viu-se, portanto, que o estudo por HRpQCT de 51 mulheres na pós menopausa com
diagnóstico de PHPT revelou anormalidades importantes dos compartimentos trabecular e
cortical do rádio e da tíbia. FEA e avaliação adicional por ITS confirmaram
microestrutura trabecular susceptível a fratura e redução da competência biomecânica
óssea nessa doença. Finalmente, correlações significativas entre TBS e achados da
HRpQCT, exame de alta sensibilidade mas difícil acesso, indicam que TBS tem potencial
para estimar a microarquitetura trabecular em pacientes com PHPT.
97
5- CONCLUSÕES:
A partir do estudo por HRpQCT de 51 mulheres na pós menopausa com PHPT,
comparadas a 120 controles da mesma faixa etária e estado menopausal, conclui-se que:
1. mesmo na forma assintomática de PHPT, há redução generalizada da vBMD, bem
como deterioração da microestrutura cortical e trabecular no rádio e na tíbia;
2. quando realizada ITS das imagens de HRpQCT, observa-se redução preferencial
de trabéculas em placa, com redução da razão P-R, diminuição do volume
trabecular em sentido axial e redução da conectividade entre trabéculas,
revelando microestrutura trabecular mais susceptível a fraturas;
3. FEA das imagens de HRpQCT confirma redução da rigidez de osso total e
trabecular, fornecendo explicação biomecânica para o achado clínico de aumento
do risco de fratura nessa condição.
A partir do estudo por TBS de 22 mulheres na pós menopausa com PHPT, conclui-se
que:
1. correlações significativas entre TBS e índices de densidade volumétrica,
microestrutura e rigidez de osso total estimados por HRpQCT indicam que essa
nova técnica de análise pode tornar-se útil para avaliação de pacientes com PHPT
na prática clínica.
98
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Artigo de revisão publicado sobre o tema:
Catabolic and anabolic actions of parathyroid hormone on the skeleton
J. Endocrinol. Invest 2011; 34: 801-810
Catabolic and anabolic actions of parathyroid hormoneon the skeleton
1
ABSTRACT. PTH, an 84-amino acid peptide hormone synthe-sized by the parathyroid glands, is essential for the mainte-nance of calcium homeostasis. While in its traditional metabol-ic role, PTH helps to maintain the serum calcium concentrationwithin narrow, normal limits and participates as a determinantof bone remodeling, more specific actions, described ascatabolic and anabolic are also well known. Clinically, thecatabolic effect of PTH is best represented by primary hyper-parathyroidism (PHPT), while the osteoanabolic effect of PTHis best seen when PTH or its biological amino-terminal frag-ment [PTH(1-34)] is used as a therapy for osteoporosis. Thesedual functions of PTH are unmasked under very specific patho-logical (PHPT) or therapeutic conditions. At the cellular level,
PTH favors bone resorption, mostly by affecting the receptoractivator of nuclear factor κκ-B (RANK) ligand (RANKL)-osteo-protegerin-RANK system, leading to an increase in osteoclastformation and activity. Increased bone formation due to PTHtherapy is explained best by its ability to enhance osteoblas-togenesis and/or osteoblast survival. The PTH-induced boneformation is mediated, in part, by a decrease in SOST/sclerostinexpression in osteocytes. This review focuses on the dual an-abolic and catabolic actions of PTH on bone, situations whereone is enhanced over the other, and the cellular and molecularmechanisms by which these actions are mediated. (J. Endocrinol. Invest. 34: ??-??, 2011)©2011, Editrice Kurtis
INTRODUCTIONPTH, an 84-amino acid peptide hormone, is synthesizedin the cells of the parathyroid glands. Release of PTH oc-curs both with circadian dynamics and in pulsatile fashionstochastically. Through its direct actions on bone and kid-ney, the principle target organs, and indirectly on thegastrointestinal tract (by facilitating the activation of vi-tamin D), PTH helps to maintain the serum calcium with-in narrow, normal limits. At the level of bone, it promotescalcium release; at the level of the kidney, it promotestubular calcium reabsorption. The indirect effect on thegastrointestinal tract promotes calcium absorption (1). Ahypocalcemic signal will lead to greater PTH release (andsynthesis), thus leading to these organ-specific eventsand restoring the serum calcium to normal. The direct actions of PTH are initiated by an interactionwith its receptor (PTH1R), a G-protein-coupled receptorexpressed in target cells, such as osteoblasts in bone andtubular cells in the kidney (2). Events following the bind-ing of PTH to the PTH1R include stimulation of Gαs-me-diated activation of adenyl cyclase, which in turn pro-motes cAMP production and subsequent activation ofprotein kinase A (PKA). The PTH1R is also linked to Gαq-mediated activation of phospholipase and protein kinaseC (PKC) (3, 4). Regulation of these activation events oc-curs, in part, at the level of the PTH1R when it is inter-
nalized (5). Recently, PTH has been shown to downregu-late sclerostin, an important regulator of bone formation.This effect is also mediated by cAMP signaling in osteo-cytes (6). The catabolic effect of PTH is best represented by theclassic disorder of PTH excess, primary hyperparathy-roidism (PHPT). In this setting, in which patients are ex-posed to continuously high amounts of circulating PTH,bone loss is common. When PHPT was invariably a symp-tomatic disease, bone loss was often accompanied byfractures. With the more modern clinical profile of PHPTemerging at around the time that dual energy X-ray ab-sorptiometry (DXA) became available in the 1980’s, dis-covery of PHPT was likely to be in asymptomatic individ-uals whose bone loss could be gleaned only by DXA. In-sights into this phenotype revealed clues to the anabol-ic proclivity of this hormone (7), namely that cancellousbone microstructure is preserved in comparison to post-menopausal women without PHPT (8-10).Further insight that exploited the idea that PTH could beprimarily anabolic under certain circumstances came inthe 1990’s when studies by Dobnig et al. (11) showedthat the way in which PTH is administered dictateswhether it will serve primarily an anabolic or catabolicrole. In rats treated once daily (i.e., intermittently) withlow doses of PTH, marked anabolic effects on the skele-ton were observed while continuous, 24-h exposure wasassociated with the catabolic effects. This key observa-tion was developed further as the foreshortened aminoterminal fragment of PTH, teriparatide [PTH(1-34)] and,later, the full-length hormone [PTH(1-84)] were shown tobe anabolic when administered once daily in low doses(12, 13). At the cellular level, gene expression profiling of inter-
Key-words: Hyperparathyroidism, osteoblastogenesis, osteoclastogenesis, PTH,PTH(1-84), teriparatide.
Correspondence: J.P. Bilezikian, MD, 630 W, 168th Street, New York, NY 10032, USA.
E-mail: [email protected]
Accepted August 24, 2011.
First published online September 23, 2011.
J. Endocrinol. Invest. 34: ???-???, 2011DOI: 10.3275/7925
B.C. Silva, A.G. Costa, N.E. Cusano, S. Kousteni, and J.P. BilezikianMetabolic Bone Diseases Unit, Division of Endocrinology, Department of Medicine, College of Physicians and Surgeons, Columbia University, USA
REVIEW ARTICLE
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mittent vs continuous PTH administration in vivo and invitro suggests that the two modes of administration ofPTH can regulate different set of genes, one favoringbone formation and the other favoring bone resorption(14, 15). This review focuses on both the anabolic and catabolicskeletal effects of PTH, and discusses the cellular basisby which PTH exerts these effects.
PHPTHistorically, symptomatic PHPT is associated with a dev-astating, catabolic destruction of the skeleton with boneloss, brown tumors, bone cysts, and subperiosteal boneresorption of the phalanges (16, 17). Osteitis fibrosa cys-tica, the term given to this severe bone disease, is stillseen in the developing world, but in most regions wherebiochemical screening is routine, asymptomatic PHPTpredominates. Asymptomatic PHPT rarely is accompa-nied by these specific skeletal features (18-20). Rather,bone densitometry technology has permitted a differentkind of insight into the skeleton of subjects with PHPT.
Bone density and skeletal microarchitectureSilverberg et al. (7) evaluated the presence and extent ofbone disease in patients with asymptomatic PHPT, byDXA and by histomorphometry of bone biopsies. Thegreatest reduction in bone mineral density (BMD) wasfound at the distal 1/3 radius, a site of predominantly cor-tical bone. The ability to perform 3-site DXA gave furtherinformation at the other 2 sites, the lumbar spine, a siteprimarily comprised of cancellous bone, and the hip, asite that is an even admixture of cortical and cancellousbone. BMD of the lumbar spine was within 5% of ex-pected for non-hyperparathyroid, post-menopausal wom-en. The hip regions showed values that were intermedi-ate between the preferentially reduced cortical bone ofthe distal radius and the maintained BMD of the lumbarspine (Fig. 1). The findings by DXA were followed up by an extensive
series of histomorphometric studies by Dempster et al.(7, 9, 10, 21). Preferential involvement of cortical bonewith preservation of cancellous areas was confirmed byhistomorphometric analysis. The vast majority of patientswith PHPT showed reductions in cortical width. In con-trast, the cancellous compartment of the bone biopsyspecimen showed greater than average values for tra-becular bone volume. Other features of trabecular bonesuch as trabecular number, connectivity and separationindicated preservation of this compartment of bone inmost patients with PHPT. Analysis of bone biopsy spec-imens by microcomputed tomography (µCT) also demon-strated in mild PHPT preserved cancellous bone archi-tecture (Fig. 2) (8). Histomorphometric studies of bonebiopsies in PHPT have confirmed that while the trabecu-lar compartment is preserved, the cortical compartmentis at risk with cortical thinning and increased corticalporosity commonly seen (9, 10, 21, 22). The 10- and 15-yr natural history studies of Silverberg etal. (18, 20) showed that lumbar spine bone density re-mains stable for as long as subjects were followed, whilethe sites with more cortical bone, namely the distal 1/3 ra-dius and the femoral neck, began to experience sub-stantial declines after 10 yr of observation.The characteristic densitometric and histomorphomet-ric pattern described above, with preferential reductionof the cortical compartment, is not always seen in PH-PT. The descriptions provided are the most commonones. Obviously, these features will vary with the extentof the disease, and predisposing factors that could fa-vor losses in other skeletal compartments and thus oth-er patterns. For example, Silverberg et al. described aminority of patients with PHPT whose lumbar spine bonedensity was preferentially reduced (23). This could re-flect preferential loss of cancellous bone due to themenopause per se, prior to the development of PHPT.Other studies have demonstrated more universal loss ofBMD in PHPT (24-26), a finding that would not be un-expected in patients with more severe disease. Recent-ly, Hansen et al. (24), using a newer non-invasive tech-nology, high-resolution peripheral CT (HR-pQCT),showed decreased bone mass in the radius in both thecortical and trabecular compartments, in 27 women withmild PHPT, as compared to a normal control group. Inthis study, subjects with PHPT had reduced BMD at thelumbar spine by DXA. It is not surprising, therefore, thatthe cancellous compartment would be abnormal by HR-pQCT in this cohort. It is likely that when more typicalphenotype of PHPT is examined by HR-pQCT, mi-crostructural analysis by HR-pQCT will be consistent withpreserved cancellous bone.
Fracture riskGiven the catabolic skeletal actions of continuously ele-vated PTH levels, typically at cortical sites, one would ex-pect increased non-vertebral fracture risk in patients withPHPT. The preserved cancellous skeleton would be ex-pected to be associated with reduced fracture risk in thespine. Some studies, though, have reported an increasein overall fracture risk (27, 28), including vertebral (17, 28,29), forearm, rib, and pelvic fractures (28) in PHPT. In-creased risk of vertebral and hip fractures has not, how-
*
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Fig. 1 - The densitometric signature of primary hyperparathy-roidism (PHPT) in the modern era. Bone densitometry at lumbarspine, femoral neck and radius in PHPT. Bone mineral density(BMD) is presented in comparison to expected values for nor-mal controls. [Adapted from (7)].
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ever, been uniformly observed (30-32). These controver-sial findings may reflect reports that vary in the severity ofthe PHPT. Vignali et al. (29) assessed vertebral fracturerisk in 150 subjects with PHPT according to the severityof the disease. Patients with symptomatic PHPT had ahigher rate of vertebral fracture than patients with asymp-tomatic PHPT. When subjects with asymptomatic PHPTwere classified according to whether they did or did notmeet the criteria for surgery, established by the 2002Workshop on asymptomatic PHPT, the rate of fracturewas significant in those who met surgical guidelines butnot in those who did not meet surgical guidelines. It is hard to draw any conclusions from these studies be-cause many of them are observational and cross-sec-tional. Some studies suffer by a surveillance bias in whichthe known PHPT state may have been more likely to beassociated with x-rays for complaints of back pain, for ex-ample. It is still not clear, then, whether or not patientswith mild, asymptomatic PHPT have increased fracturerisk. There are structural issues that may confound the simpleexpectations by BMD of increased fracture risk at corticalsites and reduced fracture risk at cancellous sites in PH-PT. PTH is known, for example, to have other effects onbone qualities beside BMD. As reported in many series,preserved cancellous microarchitecture in mild PHPTmight counteract the cortical thinning at cortical sites.Moreover, PTH may increase periosteal apposition, lead-ing to an increase in cross sectional diameter of the bone,favorably altering bone geometry (33, 34). The increasein the outer diameter of bone will increase bone strengthindependent of BMD (35). Thus, a number of other fac-tors have to be taken into account that altogether de-fines fracture risk in PHPT.
PTH AS AN ANABOLIC SKELETAL THERAPYThe clues described earlier to the anabolic potential ofPTH led to its successful development and that of its bi-ologically active but foreshortened fragment, PTH(1-34)as a therapy for osteoporosis. PTH represents the onlyosteoanabolic class available at this time for the treat-ment of osteoporosis. These PTH forms have been shownto increase BMD, improve microarchitecture of the bone,and reduce vertebral fractures. For teriparatide [PTH(1-34)], a reduction in non-vertebral fractures has also beendemonstrated (12, 13, 36-41).
Mode of actionTreatment with PTH leads to an increase in bone turnover,with an interesting bitemporal characteristic, in whichthere is an early stimulation of bone formation followedlater by a stimulation of bone turnover (bone resorptionand bone formation). The dichomatous kinetics betweenearly effects on bone formation (a bone modeling effect)and a general increase in bone turnover (a bone remod-eling effect) has led to the concept of an “anabolic win-dow”, the period of time when PTH is maximally anabol-ic (Fig. 3) (13, 42-45). Even when bone remodeling is stim-ulated, for at least a limited period of time, bone forma-tion exceeds bone resorption, continuing the anabolicproperty of PTH albeit perhaps less marked.The concept of the anabolic window is supported not on-ly by studies of the kinetics of bone markers in the circu-lation but also by histomorphometric analysis of iliac crestbone biopsies. Using techniques of standard double-la-beling and novel quadruple labeling techniques, it hasbeen demonstrated by Dempster et al. (46) that PTH ini-tially stimulates bone formation without prior resorption.This suggests that the process of bone accrual is occur-
Inde
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urno
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Peak
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Bone resorptionmarkers
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Fig. 3 - PTH as an anabolic agent for bone: a kinetic model.Treatment with PTH leads to increased bone turnover, with anearly stimulation of bone formation followed later by a stimula-tion of bone resorption. It is thus formed an “anabolic window”,the period of time when PTH is maximally anabolic. When boneformation and resorption are stimulated, bone formation ex-ceeds bone resorption, continuing the anabolic property of PTH.[Adapted from (45)]
Fig. 2 - Microarchitectural features in pre-and post-menopausal women with pri-mary hyperparathyroidism (PHPT). 3D mi-corcomputed tomography reconstruc-tions of cancellous bone in pre- and post-menopausal women with PHPT (B and D),and normal controls (A and C).[Adapted from (8)].
ControlBV/TV = 30.3%
PHPTBV/TV = 30.5%
ControlBV/TV = 21.1%
PHPTBV/TV = 25.3%
A BPre-menopausal Post-menopausal
C D
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ring on quiescent bone surfaces, which is classically amodeling-based event. Modeling is not usually observedin normal, adult human bone, but would appear to oc-cur in this special situation of early PTH exposure (47).Lindsay et al. (46) evaluated bone biopsies of 10 post-menopausal women treated with teriparatide for 4 weeksand compared them to a matched control group. Theauthors relied on the appearance of the bone surface un-derneath the newly formed bone to classify the bone for-mation as modeling or remodeling-based. In the case ofmodeling-based bone formation, the surface underneathnewly formed bone is smooth, and the collagen fibershave similar orientation to the adjacent bone tissue. Inremodeling-based bone formation, that surface is irreg-ular, with interrupted collagen fibers, indicating that boneresorption has occurred (47). In the analysis, modeling-based bone formation with teriparatide accounted forapproximately 30% and 22% of the bone formation incancellous and endocortical bone respectively. In con-trol subjects, formation was exclusively remodeling-based(46). In agreement with the concept of the anabolic win-dow, the ability of PTH to increase bone formation in theabsence of prior resorption appears to be more pro-nounced in the early stages of the therapy, since the pro-portion of modeling-based bone formation decreasesover the course of the treatment. When biopsies are car-ried out after 12-24 months after treatment with 20 or 40µg daily of teriparatide treatment, only 2.8% and 7.7%,respectively, of bone formation in cancellous bone was amodeling process (38). The modeling-based bone for-mation induced by PTH can occur not only on quiescentbone surfaces, but also in areas of remodeling in whichthere is overfilling of bone resorption pits with extensionof bone formation beyond the margins of the resorptioncavity (46-48). Anabolic action also is appreciated whenremodeling becomes the dominant profile of PTH actionbecause there is more bone formation occurring thanbone resorption (47).
Bone density and microarchitectureDensitometric findings in men and women who are treat-ed with PTH(1-84) or teriparatide demonstrate major in-crements in BMD at the lumbar spine (12, 13, 40, 44). Byhistomorphometry and µCT of paired iliac crest biopsyspecimens from women treated with teriparatide for 11-24 months, improvements in cancellous bone volume,connectivity, and cancellous bone morphology with con-version from a more rod-like to a more normal plate-likeappearance have been appreciated (39). Similar effectson cancellous bone were seen upon administration ofPTH(1-84) for 18 or 24 months (Fig. 4) (37, 41). Smaller increases in BMD are appreciated at the hip sites(total hip and femoral neck). The 1/3 radial site typicallyis not increased and may actually show a small reductionin BMD (12, 13, 40, 44). The small or even negative ef-fects of PTH on BMD at sites containing predominantlycortical bone were not confirmed when bone microar-chitecture was assessed. Dempster et al. (36) have shownmaintenance or an increase in cortical width in men andwomen treated with teriparatide for 18 and 36 months,respectively, without increases in cortical porosity. Im-ages obtained during µCT analysis suggest that the in-
crease in cortical thickness seen with teriparatide resultsfrom increased bone formation at both the periosteal andendosteal surfaces (39). The increase in cortical thickness,however, is not always seen (37, 41).
Bone geometry and fracture risk Iliac crest bone biopsies from post-menopausal womentreated with teriparatide for 1 month confirm a 4- to 5-fold increase in bone formation rate on the cancellous,endocortical, and periosteal surfaces when compared toa control a group. The increase in bone formation rateon the periosteal surface suggests that PTH has also thepotential to increase bone diameter (48). Bone geometry was assessed by peripheral quantitativeCT (pQCT) in a subgroup of 101 women enrolled in theteriparatide fracture prevention trial, at the forearm, thesite at which cortical bone predominates (49). There weresignificant increases in cortical bone area, total bone min-eral content and total bone area in teriparatide-treatedsubjects (20 or 40 µg daily) as compared to patients re-ceiving placebo. Cortical thickness was not changed. Pe-riosteal circumference was significantly higher in bothteriparatide groups, as well as the polar cross-sectionalmoment of inertia. These changes in bone geometry areknown to be associated with increased bone strengthand improved resistance to fracture (49).Although PTH can increase cortical porosity and boneresorption at the inner endocortical surface of the bone,it can stimulate periosteal bone apposition, and conse-
Fig. 4 - Microcomputed tomography images of iliac crest biop-sies of postmenopausal women treated with either PTH(1-84) orteriparatide. A) Osteoporotic postmenopausal women treatedwith placebo or PTH(1-84) for 18 months. B) Paired biopsy spec-imens from a 64-yr-old woman before and after treatment withteriparatide for 36 months. [Adapted from (36, 37)].
Teriparatide
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quently, increase the outer diameter of the bone. Theperiosteal apposition partly offsets the loss of compres-sive and bending strength produced by cortical thinningand porosity, and the resultant change in the ratio of theouter to inner diameter of bone, leads, ultimately, to in-creased bone strength (45, 50). This favorable change inbone geometry observed with PTH could well accountfor the reduction in non-vertebral fracture risk (12), eventhough BMD is not changed or somewhat reduced atcortical sites. The paradox of reduced cortical BMD andreduced fracture risk at sites of cortical bone is thus ex-plained by these affects of PTH on bone size and mi-crostructure.
CELLULAR ACTIONS OF PTH ON THE SKELETONCellular actions of PTH contributing to increased boneresorption: Catabolic Increased bone resorption is the most recognizedcatabolic action of PTH. It is one of the essential mecha-nisms by which PTH maintains calcium homeostasis, par-ticularly in the face of a hypocalcemic stimulus. In vivo,PTH enhances bone resorption by increasing osteoclas-tic activity. However, in vitro studies demonstrate thatosteoclast-like cells in culture do not show increased ac-tivity in response to PTH, unless osteoclasts are co-cul-tured with stromal or osteoblast-like cells or conditionedmedium from osteoblasts previously treated with PTH(51-53). It is likely therefore, that PTH induces bone re-sorption by activating osteoclasts indirectly, through itsactions on osteoblasts. In osteoblasts, PTH regulates the expression of the re-ceptor activator of nuclear factor-κB (RANK) ligand (RAN-KL), and its soluble decoy receptor osteoprotegerin(OPG), which both play a dominant role in osteoclasto-genesis (54-56). RANKL, a tumor necrosis factor (TNF)
family member, binds to the RANK on the surface ofhematopoietic precursors of osteoclast, promoting theirdifferentiation and survival. RANKL also stimulates fullyformed osteoclasts. The catabolic effects of RANKL areinhibited by OPG, a TNF receptor family member thatbinds to RANKL and thereby prevents access of RANKLto its receptor RANK. The balance between amounts ofRANKL and OPG is a determinant of osteoclastogenesis(57). Continuous infusion of PTH increases RANKL andinhibits OPG mRNA expression in primary murine os-teoblasts and in bone from rats (54, 55, 58). In vitro stud-ies conducted by Fu et al. (59) showed that PTH directlyincreases RANKL expression by activation of cAMP/PKA-CREB pathway, and inhibits OPG expression via a PKA-CREB-AP-1 pathway. These PTH actions lead to an in-crease in the RANKL/OPG ratio, which is believed to bethe main mechanism by which PTH influences osteoclas-togenesis and bone resorption (Fig. 5). Clinical studies also argue for RANKL as a key interme-diate in the catabolic actions of PTH. Circulating levelsof RANKL were elevated in 29 patients with mild PHPT,correlating positively with bone resorption markers andwith rates of bone loss at the total femur (60). The RAN-KL/OPG ratio, as determined by mRNA analysis of bonebiopsies, significantly declines after parathyroid surgery(61). The pre-operative RANKL/OPG ratio correlated pos-itively with 1-yr post-operative increases in bone mass. In addition to the RANKL/OPG system, it has been re-ported that the monocyte chemoattractant protein-1(MCP-1) can mediate the action of PTH on osteoclasto-genesis. PTH increases the expression of MCP-1 in ratosteoblastic cells and in the femur of rats treated with in-termittent or continuous infusion of PTH via the PKApathway (62). MCP-1 promotes chemoattraction of pre-osteoclasts, and enhances RANKL-induced osteoclasto-genesis and fusion, contributing to the increase in bone
Fig. 5 - Anabolic and catabolic pathwaysof PTH on the skeleton. A) PTH decreas-es SOST/sclerostin expression in osteo-cytes. Sclerostin functions as a negativeregulator of bone formation, and itsdownregulation by PTH contributes forthe PTH-induced osteoanabolism. B)PTH favors bone resorption, mostly byincreasing receptor activator of nuclearfactor kappa-B ligand (RANKL) and de-creasing osteoprotegerin (OPG) expres-sion in osteoblasts, which ultimatelyleads to an increase in osteoclast forma-tion and activity.
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resorption (62). Although the increase in MCP-1 expres-sion was more pronounced in rats treated with intermit-tent doses of PTH than in rats treated with continuous in-fusion of this hormone, the latter mode of administrationled to moderated but sustained up-regulation of MCP-1mRNA levels, explaining the catabolic action of PTH ob-served upon continuous infusion of PTH. Although many studies have failed to demonstrate con-sistently a direct effect of PTH on osteoclasts, Langub etal. (63) showed that the PTH receptor PTH1R is expressedin osteoclasts from patients with the secondary hyper-parathyroidism of chronic kidney disease. More recently,Dempster et al. (64), have also demonstrated that thePTH1R is expressed in human osteoclasts derived fromperipheral blood mononuclear cells at the mRNA andprotein level. It is still unclear, though, if PTH can direct-ly activate osteoclasts independent of its actions on os-teoblasts.
Cellular actions of PTH contributing to increased bone formation: Osteoanabolic Pre-clinical and clinical studies have demonstrated thatintermittent administration of PTH promotes bone for-mation (12, 13, 65-67). The anabolic actions of PTH onbone mass depend on its direct action on cells of os-teoblastic lineage. Following the interaction PTH-PTH1R(6), Gαs and Gαq are activated, with subsequent activa-tion of PKA and PKC. It has been demonstrated thatcAMP/PKA signaling is a dominant mechanism by whichPTH increases bone anabolism, and that PKC is not re-quired for the osteoanabolic action of PTH (68). In fact, arecent study showed that the Gαq-PKC signal in os-teoblasts is inhibitory to the anabolic actions of PTH onbone mass (69). The osteoanabolic action of PTH is due to its ability toincrease osteoblast number, which can be achieved byan increase in osteoblastogenesis, decrease in osteoblastapoptosis or a combination of the two events (70, 71).The increase in osteoblastogenesis is explained mostlyby an increase in osteoblast differentiation rather thanincreased proliferation. It is generally accepted that dif-ferentiation requires exit from the cell cycle and, as a re-sult, proliferation is attenuated as differentiation proceeds(71). Thus, it has been suggested that one of the mech-anisms by which PTH promotes its anabolic actions is toarrest the cell cycle progression of osteoblasts, enhanc-ing their commitment to a differentiated osteogenic fate(72). Indeed, anti-proliferative effects have been report-ed in osteoblastic cell lines, cultures of primary cells, andin rodents treated with PTH, which is explained by bothan attenuation of the expression of cyclin D1, a proteinrequired for cell cycle progression, and an increase in theexpression of the cell cycle inhibitors p27Kip1 and p21Cip1
(73-75). However, the effect of PTH on osteoblast prolif-eration may be specific to the differentiation/develop -mental stage of the osteoblastic cell. Although PTH sup-presses proliferation of committed osteoprogenitor cells,there is evidence that suggests that it does not affect orincrease the replication of uncommitted osteoblast pro-genitors (71, 73, 75, 76). In agreement with these data, invitro and in vivo studies in rodents conducted by Ogita etal. (77), showed that cyclic PTH treatment promotes os-
teoblast differentiation from periosteum-derived mes-enchymal progenitors, and has a biphasic effect to en-hance, then suppress proliferation of periosteal os-teoblast progenitors.Beyond the effects on the cell cycle itself, PTH enhancesosteoblast differentiation. It stimulates osteoblast differ-entiation and osteoblastic lineage commitment in pri-mary calvarial cells, bone marrow-derived, and in pe-riosteal cells (15, 77, 78). Evidence from in vitro and invivo studies suggests that PTH increases the expressionof genes that typically signal bone formation, such as theosteoblast-specific transcription factor Runx2, as well asalkaline phosphatase (79), collagen type I alpha 1(COL1A1), and osteocalcin (14, 15, 78, 80). Recently, anovel bone formation-related factor, Tmem119, wasshown to be rapidly stimulated in mouse osteoblastic celllines by PTH (81). Consistent with a PTH-induced increasein the number of differentiating osteoblasts, intermittentPTH enhances ossicle development from bone marrowderived stromal cells implanted into immunocompro-mised mice (82).Alternatively, PTH can increase osteoblast number by de-creasing osteoblast apoptosis. Daily injections of PTH toadult mice showed an anti-apoptotic effect of PTH on os-teoblasts in femoral and vertebral sections (83). Theprevalence of osteoblast apoptosis was inversely corre-lated with serum osteocalcin, bone formation rate, andosteoblast number, suggesting that the prosurvival ef-fect of PTH on osteoblasts accounts, at least in part, forits anabolic effect on bone (83). In vitro, PTH treatment al-so inhibits pro-apoptotic effects of dexamethasone,etoposide, hydrogen peroxide induced oxidative stress,UV irradiation, serum withdrawal and nutrient depriva-tion in a variety of osteoblastic cells (79, 83, 84). Mecha-nistically, PTH phosphorylates and inactivates the pro-apoptotic protein Bad, and increases the expression ofsurvival genes like Bcl-2. These actions are mediated byactivation of PKA (83). The increased expression of Runx2is also required for the anti-apoptotic effect of intermit-tent PTH (83). Moreover, it was recently shown that PTHtreatment of cultured osteoblasts augments DNA repair,and enhances cell survival under extreme metabolicstress and direct DNA damage, which was proposed asanother mechanism by which PTH can suppress os-teoblast apoptosis (84).
MEDIATORS OF PTH ACTIONS ON BONE FORMATIONSclerostinSclerostin, a product of the SOST gene expressed pri-marily by osteocytes, is a secreted glycoprotein that func-tions as a key negative regulator of bone formation (85).In the human genetic diseases van Buchem’s disease andsclerosteosis, reduced sclerostin concentration and/oractivity are translated into generalized and progressiveovergrowth of bone and sclerosis of the skeleton (86-88).Likewise, Sost knockout mice have high bone mass. Pre-clinical studies show that an antisclerostin antibody hasosteoanabolic effects in rodents (89, 90). Early studies inhuman subjects are also confirming the anabolic effectsof an antisclerostin antibody (91).
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The finding that osteocytes secrete sclerostin, and expressthe PTH1R (92) raised the hypothesis that the osteocyte-derived sclerostin could be a mediator of the anabolic ac-tion of PTH on the skeleton. Indeed, downregulation ofSOST/sclerostin by PTH has been demonstrated in vitro,in animals, and in humans, and the regulation of SOST bythis hormone is currently recognized as having a key rolein PTH-induced bone formation (Fig. 5) (93-98). PTH de-creases Sost mRNA levels in vitro, and in rodents treatedwith either continuous or intermittent administration ofPTH (93, 96). Similarly, transgenic mice overexpressing aconstitutively active PTH1R specifically in osteocytes, haveincreased bone mass, and decreased Sost expression (94).In these mice, concomitant overexpression of Sost, also inosteocytes, abolishes the increase in cortical bone area,periosteal bone formation rate, and cancellous bone vol-ume, supporting the hypothesis that the anabolic effect ofPTH requires downregulation of sclerostin in osteocytes(94). In human subjects, serum sclerostin levels are re-ported to be lower in patients with PHPT than in controls,and a negative correlation between circulating sclerostinand PTH is observed (97-99). Moreover, intermittent PTHtherapy in post-menopausal women decreases circulat-ing sclerostin levels, which sustains the idea that thedownregulation of sclerostin accounts for the osteoan-abolic action of PTH also in humans (95). The mechanism by which sclerostin inhibits bone forma-tion is not completely understood. Until recently, it wasassumed that sclerostin would pass through the osteo-cytic canaliculi to access the bone surface, where it wouldbind to the LDL-receptor related protein (LRP) 5 and 6, in-hibiting the osteoblastic canonical Wnt/β-catenin signal-ing (6, 100, 101). In this way, sclerostin would antagonizethe pro-differentiating and survival actions of Wnts onosteoblasts. However, an effect through LRP5 in the Wntsignaling pathway has recently been questioned by stud-ies suggesting that LRP5 does not function as a Wnt core-ceptor (102). Thus, the definition mechanism(s) by whichsclerostin inhibits bone formation is still unknown.
IGFIGF-I is a regulator of cell growth and function, and, inosteoblasts, acts as a prodifferentiating and a prosurvivalfactor. PTH can induce skeletal expression of IGF-I, whichwould act as an autocrine/paracrine factor to mediate thePTH effects on osteoblasts (103, 104). Indeed, animalstudies have shown that IGF-I plays a key role in the os-teoanabolic effects of PTH. IGF-I-deficient mice had anattenuated effect of the anabolic actions of PTH on cor-tical bone (105), and deletion of the insulin receptor sub-strate adapting molecule-1 (which transmits IGF-I recep-tor signaling) blunted the anabolic response to intermit-tent PTH administration (106). The anabolic actions ofPTH on bone were also altered in mice with deletion ofthe IGF-I receptor specifically in mature osteoblasts (103).Increased cancellous bone volume at the primary spon-giosa, and enhanced bone formation, mineralization, andcortical thickness at the cortical bone observed upon PTHadministration to the control mice were blunted in theIGF-I receptor knockout mice (103). At the cellular level,IGF-I receptor deletion decreased the ability of PTH tostimulate osteoprogenitor cell proliferation and differen-
tiation, as measured by the number of ALP-expressingcolonies and mineralized nodules in cultures of bone mar-row-derived stromal cells treated with PTH.
The role of T cells T cells that express PTH receptors may be involved inboth the anabolic and catabolic actions of PTH throughCD40 Ligand, a surface molecule of activated T cells thatinduces CD40 signaling in stromal cells (107, 108). Thework of Pacifici et al. has shown that deletion of T cells orT cell-expressed CD40 Ligand blunts the catabolic activ-ity of PTH in bone by decreasing bone marrow stromalcell number, RANK/OPG production and osteoclasto-genic activity (109). Silencing of the PTH receptor in Tcells also blocks the bone loss and the osteoclastic ex-pansion induced by continuous PTH, thus demonstrat-ing that PTH signaling in T cells may also be central toPTH-induced bone loss. T cells also play a permissive rolein the anabolic effect of intermittent PTH, which is re-duced in T cell-deficient mice. The mechanism involvesactivation of Wnt signaling by T cells in pre-osteoblasts.
CONCLUSIONThe human skeleton is being renewed constantly by thedynamic process of bone remodeling, which consists oftwo normally balanced phases of bone resorption andbone formation. When these two processes are balanced,bone is neither gained nor lost. An imbalance betweenthese two, favoring bone resorption, results in a catabol-ic net effect on bone mass, while an anabolic net effectensues if bone formation exceeds bone resorption. Al-though the increase in bone resorption was the most rec-ognized action of PTH in the skeleton, this hormone can,indeed, increase bone formation, and its final effect onbone mass, either catabolic or anabolic, will depend onwhich process or processes are being favored. Continuous exposure to high levels of PTH is associatedwith catabolic effects on bone, while intermittent expo-sure to low doses of PTH has anabolic actions. The formeris exemplified by the chronic disorder of PTH excess, PH-PT, and the second is best represented by the use of PTHto treat osteoporosis. However, it is now recognized thatPTH can have anabolic effects even in states of continu-ously elevated PTH, as evidenced by a preserved can-cellous bone and a normal or greater trabecular connec-tivity observed in patients with PHPT. Similarly, decreasein BMD at cortical sites can be appreciated in subjectsbeing treated with PTH, which, however, does not lead tonegative effects on bone strength. In fact, decrease infacture risk at vertebral and non-vertebral sites wasdemonstrated in patients treated with PTH.Mechanistically, although PTH can regulate different setsof genes when it is administered intermittently or con-tinuously, favoring bone formation or resorption, re-spectively, some genes are regulated in the same wayupon continuous or intermittent endogenous exposureto PTH. Decreased circulating sclerostin levels, for ex-ample, are observed in patients with PHPT, as well as inpatients treated with recombinant PTH. In the same way,Sost mRNA levels decrease in rodents treated with ei-ther continuous or intermittent administration of PTH.
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Despite advances in elucidating the mechanism of actionof PTH on bone, the different skeletal responses to PTHare still incompletely understood. Although the responseto PTH can be clearly catabolic or anabolic dependingon the mode of exposure to this hormone, increases anddecreases in bone mass at different skeletal sites can ac-tually coexist in the same subject or condition. Futurestudies may elucidate a means to perturb molecular path-ways that are regulated by PTH so that the anabolic re-sponse to this hormone is primarily expressed. Thenthese new insights could be applied into a medical ther-apy for PHPT.
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